DE112016002739B4 - Headlight device and lighting device - Google Patents

Abstract

A lighting device (103, 108) comprising: a light source (2, 27, 2r, 2g, 2b) that emits light; a condensing optical element (3, 37, 38) that emits the light from the light source (2, 27, 2r, 2g, 2b) converts emitted light into concentrated light and emits the concentrated light; a luminous element (53a) which receives, as excitation light, the light emitted from the condensing optical element (3, 37, 38) and emits a single type of fluorescent light; a projection lens (6) that projects the fluorescent light emitted from the luminous element (53a); a wavelength selection element (7) that selects wavelengths of light passing through the wavelength selection element and light of wavelengths other than the selected wavelengths, reflected, wherein the wavelength selection element (7) is located between the condensing optical element (3, 37, 38) and the luminous element (53a), and that the concentrated light to the luminous element (53a) is transmitted and part of the fluorescent light is reflected to the projection lens (6); anda plate-like transmission element (4) which transmits the concentrated light, the transmission element (4) being arranged between the condensing optical element (3, 37, 38) and the wavelength selection element (7) and rotatable about an axis (S2) perpendicular to an optical axis (Cp) of the projection lens (6) is supported, wherein a light concentration position of the concentrated light is between the condensing optical element (3, 37, 38) and the projection lens (6), the light concentration position between the transmission element (4) and the projection lens (6) is arranged, wherein the wavelength selection element (7) includes a plurality of regions (7a, 7b, 7c) which transmit light of different wavelengths and which are arranged in a direction (Y-axis direction) perpendicular to the optical axis (Cp ) of the projection lens (6) are arranged, and wherein the lighting device (103, 108) rotates the transmission element (4) to the position at which the ko n-centered light reaches the wavelength selection element (7) to shift in a direction (Y-axis direction) perpendicular to the optical axis (Cp) of the projection lens (6) and thereby change the color temperature of the light projected from the projection lens (6).

Description

Technical area

The present invention relates to a headlight device and a lighting device using a light source and an optical element.

State of the art

In recent years, there has been an increasing demand for a headlamp device capable of changing a light distribution pattern including an irradiation direction depending on the running condition of a vehicle.

There are similar requirements for lighting devices. For example, when displaying goods or the like, the display effect is improved by changing the color of light illuminating the goods, the spot size or lighting position of illuminating light, or the like.

For sub-light sources (lighting fixtures) installed in shops or other locations, it is common practice to manually change the directions of irradiation. Therefore, in order to improve the convenience, the ability to automatically change the irradiation directions is required.

A lighting device capable of changing the light distribution, lighting position, or the like can be used not only for vehicles but also for other purposes.

As for lighting devices capable of changing the irradiation direction, taking a headlight device for a vehicle as an example, Patent Document 1 can be cited as an example. Patent Document 1 discloses a mechanism that changes an irradiation direction of a first sub-lamp unit in a left-right direction or an up-down direction by pivoting and rotating a semiconductor light emitting element, a reflector and a projection lens in an integrated manner. Further, it discloses a mechanism that changes an irradiation direction by leveling and moving up and down only a projection lens held by a lens holder. Other prior art lighting devices are shown in Patent Documents 2 and 3.

List of citations

Patent literature

• Patent Document 1: Japanese Patent Application Publication JP 2009-87811 A ( 2 and 8th )
• Patent Document 2: Japanese Patent Application Publication JP 2009-224039 A
• Patent Document 3: United States Patent Application Publication US 2012/0074833 A1

Summary of the invention

Technical problem

However, the configuration according to Patent Document 1 pivots and rotates the semiconductor light emitting element, the reflector and the projection lens at the same time. Thus, the mechanism for changing the direction of irradiation is complicated. Furthermore, a projection lens of a typical headlamp device is large. Thus, if only the projection lens is adjusted in height and driven, the headlamp device is large when viewed from the front, and the load on the drive mechanism is high.

the solution of the problem

This problem is solved by a lighting device according to claim 1. Such a lighting device includes, in particular: a light source that emits light; a condensing optical element that converts the light emitted from the light source into concentrated light and emits the concentrated light; a luminous element that receives, as excitation light, the light emitted from the condensing optical element and emits a single type of fluorescent light; and a projection lens that projects the fluorescent light emitted from the luminous element, a light concentration position of the concentrated light being between the condensing optical element and the projection lens, the light concentration position being shifted in a direction perpendicular to an optical axis of the projection lens.

Advantageous Effects of the Invention

It is possible to provide a lighting device with a simple configuration that prevents the device from increasing in size and that is capable of changing an irradiation direction.

Figure list

• 1 Fig. 13 is a configuration diagram schematically showing the main components of a headlamp device 1 illustrated according to a first embodiment of the present invention.
• 2 Fig. 13 is an explanatory diagram for explaining a configuration of a luminous element.
• 3 FIG. 12 is a configuration diagram schematically showing another configuration of the headlamp device 1 illustrated after a first modification.
• 4th Fig. 13 is a configuration diagram schematically showing the main components of a headlamp device 1 illustrated after a second modification.
• 5 Fig. 13 is an explanatory diagram for explaining a configuration of a wavelength selection element.
• 6th Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after passing through a region 7b and emitted from a luminous element according to the second modification.
• 7th Fig. 13 is a diagram illustrating an example of a transmittance-wavelength characteristic of the region 7b of the second modification.
• 8th Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after passing through a region 7a and emitted from the luminous element in the second modification.
• 9 Fig. 13 is a diagram illustrating an example of a transmittance-wavelength characteristic of the region 7a according to the second modification.
• 10 Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after passing through a region 7c and emitted from the luminous element according to the second modification.
• 11th Fig. 13 is a diagram illustrating an example of a transmittance-wavelength characteristic of the region 7c according to the second modification.
• 12th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 101 according to a second embodiment of the present invention.
• 13th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 102 according to a third embodiment of the present invention.
• 14th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 103 according to a fourth embodiment of the present invention.
• 15A , 15B and 15C are explanatory diagrams illustrating results of simulation of light ray tracing indicating the effects of the present invention.
• 16 Fig. 13 is a schematic diagram of light beams for explaining the effects of a fourth embodiment.
• 17th FIG. 14 is a schematic configuration diagram of a headlamp device 104 illustrating another exemplary configuration.
• 18th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 104a of a fifth embodiment of the present invention.
• 19th Fig. 13 is a schematic diagram of a circular plate according to the fifth embodiment.
• 20th Fig. 13 is a schematic diagram of a circular plate according to a third modification.
• 21 Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 105 according to a sixth embodiment of the present invention.
• 22nd Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 107 according to a seventh embodiment of the present invention.
• 23A , 23B and 23C are explanatory diagrams illustrating simulation results of light ray tracing according to the seventh embodiment.
• 24 Fig. 13 is a configuration diagram schematically illustrating the main components of a fourth modification.
• 25A , 25B and 25C are explanatory diagrams illustrating simulation results of light ray tracing according to the fourth modification.
• 26A , 26B and 26C are explanatory diagrams illustrating results of simulation of light ray tracing indicating features of a fifth modification.

Description of exemplary embodiments

In recent years, there has been an increasing market demand for increasing options for a color temperature of illumination light emitted from a headlamp device.

For example, Japanese Patent Application Publication No. 2012-221634 discloses a headlamp that varies the size of a point of concentrated light irradiated from an excitation light source to a luminous element. This headlamp contains a first light-emitting area and a second light-emitting area, which emit fluorescence with different peak wavelengths. It maintains an irradiation area of laser light in the first light emitting area and varies an irradiation area of laser light in the second light emitting area. This headlamp varies the color temperature by taking advantage of the fact that the excited spectrum of a luminous element (the first light emitting area) located in a center is different from that of a luminous element (the second light emitting area) located on a periphery .

However, in the one disclosed in Japanese Patent Application Publication No. 2012-221634 headlights described the color of light emitted from the center of the headlamp different from that of light emitted from the periphery. This causes a problem in that the color temperature of light reaching an object varies between the center and the periphery.

Any of the lighting devices according to the first to fifth embodiments described below can improve the uniformity of color temperature of light and change the color temperature of light projected from the lighting device (including a headlight device).

In the embodiments described below, headlight devices for vehicles will be described as examples with reference to the drawings. For the convenience of explanation, the description will be made using XYZ coordinates.

It is assumed that a left-right direction of a vehicle is the Y-axis direction; the rightward direction with respect to a forward direction of the vehicle is the + Y-axis direction; the leftward direction with respect to the forward direction of the vehicle is the -Y-axis direction. Here, “forward direction” refers to a direction in which the vehicle is traveling. That is, “forward direction” refers to a direction in which the headlamp device emits light.

It is assumed that an up-down direction of the vehicle is the X-axis direction; the upward direction is the + X-axis direction; the downward direction is the -X-axis direction. The "upward direction" is a direction towards heaven; the “downward direction” is a direction towards the ground (road surface or the like).

It is assumed that the traveling direction of the vehicle is the Z-axis direction; the direction of travel is the + Z-axis direction; the opposite direction is the -Z axis direction. The + Z-axis direction is referred to as the "forward direction"; the -Z axis direction is referred to as the "backward direction". That is, the + Z-axis direction is the direction in which the headlamp device emits light. That is, the + Z-axis direction is the direction in which the lighting device emits light.

Even if there are modifications in each of the following embodiments, the modifications are numbered sequentially.

First embodiment

1 Fig. 13 is a configuration diagram schematically showing the main components of a headlamp device 1 illustrated according to the first embodiment. As in 1 is illustrated includes the headlamp device 1 a light source 2 , a condenser lens 3 and a projection lens 6th . The condenser lens 3 is arranged in a wavelength selection area 11. The wavelength selection area 11 may include a fluorescence generation area 51. The fluorescence generating area 51 contains a luminous element 5 .

<Light source 2>

The light source 2 emits light that serves as excitation light. The light source 2 is for example a light source for excitation, such as a laser diode.

The light source 2 emits, for example, ultraviolet light with a center wavelength of 405 nm, or blue light with a center wavelength of 450 nm.

An optical axis Cs of the light source 2 passes through a center of a light emitting area of a light emitting surface of the light source 2 through and is perpendicular to the light emitting surface.

<Wavelength selection area 11>

The wavelength selection area 11 selects wavelengths of fluorescence emitted from a phosphor. The wavelength selection area 11 emits the selected fluorescence as projection light. In 1 the projection light is emitted in the + Z-axis direction.

The wavelength selection area 11 is located in the + Z-axis direction from the light source 2 . The wavelength selection area 11 is optically located in the + Z-axis direction from the light source 2 . Thus, the direction of propagation can be from from the light source 2 emitted light can be changed using a mirror or the like.

In the example of 1 the wavelength selection area 11 contains the condenser lens 3 and the fluorescence generation area 51.

<Condenser lens 3>

The condenser lens 3 concentrated by the light source 2 emitted light.

The condenser lens 3 is on the side of the light source 2 from the fluorescence generation area 51 (luminous element 5 ) out.

The condenser lens 3 is an example of a condensing optical element.

In the following exemplary embodiments, for example, there is an optical axis C. the condenser lens 3 parallel to the Z axis. In the following exemplary embodiments, for example, the optical axis is correct C. coincide with the optical axis Cs and an optical axis Cp. The optical Cp is an optical axis of the projection lens described later 6th .

In each of the following exemplary embodiments, for example, the optical axes C. , Cs and Cp can be folded using a mirror or the like. However, in the drawings are the optical axes C. , Cs and Cp illustrated as straight lines.

In 1 is the condenser lens 3 illustrated as plano-convex. However, the condenser lens 3 be biconvex.

The condenser lens 3 can have any shape, as long as they light incident on the luminous element 5 of the fluorescence generation region 51 is concentrated. The condenser lens 3 can consist of two lenses.

The condenser lens 3 can be in a direction perpendicular to the optical axis C. be moved. For example, in 1 the direction perpendicular to the optical axis C. the Y-axis direction. That is, in 1 can take the condenser lens as an example 3 can be moved in the Y-axis direction.

For example, the position of the condenser lens 3 , on which the optical axis C. the condenser lens 3 with the optical axis Cp of the projection lens 6th as a reference position of the condenser lens 3 taken.

This allows the condenser lens 3 a light concentration position of excitation light emitted from the excitation light source 2 was emitted in the Y-axis direction on the luminous element 5 shift. When the condenser lens 3 consists of two lenses, the two lenses are shifted integrally in the Y-axis direction.

<Fluorescence generating area 51 and luminous element 5 >

The fluorescence generation area 51 receives through the luminous element 5 from the condenser lens 3 emitted concentrated light and emits light of different wavelengths.

The fluorescence generating area 51 contains the luminous element 5 . 2 Fig. 13 is an explanatory diagram showing an example of a configuration of the luminous element 5 illustrated. 2 Fig. 3 is a view of the luminous element 5 when viewed from the -Z axis direction side. Because the optical axis C. is parallel to the Z axis, it is in 2 represented by a black point.

The light element 5 is divided into several areas. The light element 5 is divided into several regions in a direction perpendicular to the optical axis C. divided. For example, the light element 5 divided into three areas in the Y-axis direction. For example, contains the luminous element 5 Areas 5a , 5b and 5c .

The area 5a emits fluorescence of, for example, 6000 K. The range 5b emits fluorescence of, for example, 4000 K. The area 5c emits fluorescence of, for example, 2500 K.

When the condenser lens 3 is at the reference position, the area is 5a on the optical axis C. the condenser lens 3 . The area 5b is located on the + Y-axis direction side of the optical axis, for example C. . The area 5c is located on the -Y axis direction side from the optical axis, for example C. .

The area is also located 5a on the optical axis Cp of the projection lens 6th . The area 5b is located on the + Y-axis direction side from the optical axis Cp, for example. The area 5c is located on the -Y axis direction side of the optical axis Cp, for example.

The number of areas of the luminous element 5 can be two. Depending on the intended use, the lighting element 5 be divided into areas in the X-axis direction. In this case, for example, if the condenser lens goes 3 at the reference position is the optical axis C. through one of the two areas.

The diameter of the light element 5 concentrated excitation light is, for example, 0.5 mm.

<Projection lens 6>

The projection lens 6th projects fluorescence emitted from the fluorescence generation area 51 in the + Z-axis direction. The projection lens 6th projects a light distribution pattern that is at a focal position of the projection lens 6th is formed in a direction of the optical axis Cp of the projection lens 6th in the forward direction. For example, when a focal point of the projection lens is projected onto a light-emitting surface of the luminous element 5 is located, the projection lens 6th an image corresponding to one in the light emitting surface of the luminous element 5 formed light intensity distribution.

By projecting the image of the light emitting surface of the luminous element 5 in this way, it is possible to easily form a light distribution pattern. When a circular point is formed, the luminous element 5 have a circular light emitting surface so that a circular light intensity distribution is formed. The projection lens 6th can project an image based on the shape of the light emitting surface. The projection lens 6th can project an image based on the shape of the light emitting area in the light emitting surface. In the direction of the optical axis Cp, the light concentration position coincides with the focal position of the projection lens.

<How the headlight device works 1 >

The operation of the headlight device 1 will now be described.

The condenser lens 3 is shifted in the Y-axis direction, for example.

When the condenser lens 3 is shifted in the + Y-axis direction, that plants off the condenser lens 3 emitted light continues while inclined in the + Y-axis direction. Thus, the condenser lens 3 the excitation light on the area 5b of the light element 5 focus.

When the condenser lens 3 is shifted in the -Y axis direction, plants off the condenser lens 3 emitted light while inclined in the -Y axis direction. Thus, the condenser lens 3 the excitation light on the area 5c of the light element 5 focus. The amount of displacement of the condenser lens 3 becomes dependent on the light concentration position of the excitation light on the luminous element 5 set.

16 Fig. 13 is a schematic diagram of light ray trajectories of light rays emanating from the luminous element 5 propagate out in the + Z axis direction.

In 16 the optical axis Cp coincides with the optical axis C. as in the case where the condenser lens 3 in the first embodiment is at the reference position.

From the areas 5b and 5c emitted light beams 1400b and 1400c are located on the luminous element 5 not on the optical axis C. . Thus, typically those of the areas 5b and 5c emitted light beams 1400b and 1400c obliquely to the optical axis Cp after passing through the projection lens 6th . That is, those of the areas 5b and 5c emitted light beams 1400b and 1400c are not parallel to the optical axis Cp after passing through the projection lens 6th have passed through.

However, by increasing the distance from the luminous element 5 to the projection lens 6th the positions of the light beams 1400b and 1400c relative to the position of the light beam 1400a at an irradiation position can be arranged so that there is no problem in practical use. Even if the luminous element 5 in the three areas 5a , 5b and 5c is shared by each of the areas 5a , 5b and 5c light emitted through the projection lens 6th to the extent that light parallel to the optical axis Cp is converted to the extent that there is no problem in practical use.

For example, in Europe, the projection lens 6th a distance of 60 mm from the lighting element 5 in the Z-axis direction. It will Assume that the amount of displacement of the light distribution is 0.5 degrees.

Here, in each of the exemplary embodiments, “irradiation position” refers to a position irradiated by light projected from the headlight device (lighting device). For example, irradiation positions for vehicles are determined by road traffic rules or the like. For example, in Europe, the United Nations Economic Commission for Europe (UNECE) specifies a position 25 m away from a light source as the position at which the luminous intensity of an automobile headlamp device is measured. in Japan, the Japanese Industrial Standards Committee (JIS) specifies a position 10 m from a light source as the position at which the luminous intensity is measured.

On the other hand, if the direction of the projected light is positively changed, the distance from the luminous element can 5 to the projection lens 6th be made small. By continuously or stepwise changing the distance from the luminous element 5 to the projection lens 6th the amount of shift in the light distribution direction can be changed.

Through the above process, if the optical axis C. the condenser lens 3 with the optical axis Cp of the projection lens 6th coincides with the light source 2 emitted excitation light on the area 5a of the light element 5 concentrated. When the optical axis C. the condenser lens 3 in the + Y-axis direction with respect to the optical axis Cp is shifted by the light source 2 emitted excitation light on the area 5b of the light element 5 concentrated. When the optical axis C. the condenser lens 3 in the -Y axis direction with respect to the optical axis Cp is shifted by the light source 2 emitted excitation light on the area 5c of the light element 5 concentrated.

Thus it is by sliding the condenser lens 3 possible in the Y-axis direction, the light concentration position of the excitation light on the luminous element 5 to move. This makes it possible to switch between the three color temperatures. By providing a space between each area, by providing an aluminum layer between each area, or otherwise, mixing of light rays having different color temperatures is prevented. This prevents color unevenness from occurring from the projection lens 6th emitted light.

The number of areas of the phosphor element 5 is not limited and can be two or four. The distance between the light element 5 and the projection lens 6th is such a distance that light can be obtained with parallelism which does not cause any problem in practical use. Thus, in particular, there is the luminous element 5 is always on the optical axis Cp, light after passing through the projection lens 6th parallel to the optical axis Cp.

<First modification>

3 FIG. 12 is a configuration diagram schematically showing another configuration of the headlamp device 1 illustrated according to the first embodiment of the present invention. In 3 the fluorescence generation region 51 is in FIG 1 is replaced by a fluorescence generating area 52 having a different configuration.

As in 3 As is illustrated, a wavelength selection element 700 is located in the fluorescence generation region 52 on the light source side of the luminous element 5 . The wavelength selection element 700 is between the condenser lens 3 and the light element 5 arranged. In 3 is the wavelength selection element 700 on a surface of the luminous element 5 arranged on the -Z axis side.

The wavelength selection element 700 reflects light of wavelengths other than the wavelengths of the light source 2 emitted excitation light. The wavelength selection element 700 leaves the light source 2 emitted excitation light through. The wavelength selection element 700 reflects, for example, from the luminous element 5 emitted fluorescent light.

By arranging the wavelength selection element 700, the luminous element 5 to the light source 2 fluorescent light emitted through the wavelength selection element 700 to the projection lens 6th reflected. This improves the light utilization efficiency.

The wavelength selection element 700 may include multiple ranges. The number of regions of the wavelength selection element 700 is, for example, three, similarly to the luminous element 5 . From any area of the luminous element 5 to the light source 2 emitted fluorescent light becomes the projection lens through a corresponding portion of the wavelength selection element 700 6th reflected.

Thus, the color of the headlight device becomes 1 emitted light determined by mixed light from that of each area of the luminous element 5 emitted fluorescent light and light reflected from the wavelength selection element 700. This makes it possible to use a Adjustment range for the color of the headlight device 1 to expand emitted light.

For example, in this configuration, each region of the wavelength selection element 700 can be configured in such a way that it only reflects light of wavelengths that are in from a corresponding region of the luminous element 5 emitted fluorescent light are included. The configuration of the first modification can change the efficiency of the lighting element 5 improve emitted fluorescent light.

<Second modification>

4th Fig. 13 is a configuration diagram schematically showing the main components of a headlamp device 1 illustrated after a second modification. A fluorescence generation area 53 is different in configuration from that of the first embodiment. The other components are the same as those in the first embodiment, so their descriptions are omitted.

The fluorescence generation area 53 of the second modification differs in that a luminous element 53a is not divided into a plurality of areas. That is, the luminous element 53a is formed by a single area. Furthermore, the fluorescence generation area 53 differs from the fluorescence generation area 51 in that it has a wavelength selection element 7.

As in 4th As illustrated, the wavelength selection element 7 is located on the -Z axis direction side of the luminous element 53a. The wavelength selection element 7 is located between the condenser lens 3 and the luminous element 53a. In 4th the wavelength selection element 7 is located on a surface of the luminous element 53a on the -Z axis side.

Thus reached by the light source 2 light emitted by the luminous element 53a after having passed through the wavelength selection element 7.

5 FIG. 13 is an explanatory diagram for explaining a configuration of the wavelength selection member 7. 5 Fig. 14 is a diagram of the wavelength selection member 7 when viewed from the -Z-axis direction side. Because the optical axis C. is parallel to the Z axis, it becomes in 5 represented by a black point.

The wavelength selection element 7 is divided into three areas 7a, 7b and 7c in the Y-axis direction.

The areas 7a, 7b and 7c have mutually different wavelength selection characteristics. That is, the regions 7a, 7b and 7c mutually transmit different wavelength regions.

6th Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after it has passed through the region 7a and emitted from the luminous element 53a. The vertical axis of 6th represents a relative light intensity (relative energy). The characteristic of 6th is normalized by the maximum light intensity. Thus the maximum value on the vertical axis is equal to "1". The horizontal axis of 6th represents the wavelength (nm).

In 6th is a spectrum from the light source 2 emitted excitation light, the curved line 30a shown in the wavelength range of 440 nm to 460 nm. A spectrum of fluorescent light generated by exciting the luminous element 53a is the curved line 50a shown in the wavelength range from 470 nm to 780 nm.

7th FIG. 13 is a diagram illustrating an example of a transmittance-wavelength characteristic of the region 7 a of the wavelength selection element 7. The vertical axis of 7th represents the transmittance (%). The horizontal of 7th represents the wavelength (nm).

In 7th An actual transmittance / wavelength characteristic (characteristic of transmittance with respect to wavelength) requires a wavelength width of 5 nm to 10 nm until the transmittance value stabilizes at the point of change. Thus, it is a curved line at the point of change. To simplify the explanation, in 7th does not take into account the wavelength width until the value of the transmittance has stabilized at the point of change.

7th Fig. 7 shows the characteristic that the region 7a of the wavelength selection element 7 transmits 100% of the light of wavelengths shorter than 465 nm. 7th also shows the characteristic that the region 7a reflects 100% of the light of wavelengths longer than 465 nm.

The wavelength selection element 7 leaves all of the light source in the region 7a 2 emitted excitation light through.

Part of the light passing through the region 7a is used as excitation light by the luminous element 53a. Fluorescent light generated by exciting the luminous element 53a also propagates in the -Z axis direction. However, the fluorescent light propagating in the -Z axis direction is reflected by the region 7a.

The fluorescent light reflected by the area 7 propagates in the + Z-axis direction. Thus, from the light source 2 emitted excitation light is converted, for example, into fluorescence light with a color temperature of 5000 K and emitted by the luminous element 53a (fluorescence generation region 53).

8th Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after it has passed through the region 7b and emitted from the luminous element 53a. The vertical axis of 8th represents a relative light intensity (relative energy). The characteristic of 8th is normalized by the maximum light intensity. Thus the maximum value on the vertical axis is equal to "1". The horizontal axis of 8th represents the wavelength (nm).

In 8th is a spectrum from the light source 2 emitted excitation light, the curved line 30b shown in the wavelength range of 440 nm to 460 nm. A spectrum of fluorescent light generated by exciting the luminous element 53a is the curved line 50b shown in the wavelength range from 470 nm to 780 nm.

9 FIG. 13 is a diagram illustrating an example of transmittance-wavelength characteristic (characteristic of transmittance with respect to wavelength) of the region 7 b of the wavelength selection element 7. The vertical axis of 9 represents the transmittance (%). The horizontal axis of 9 represents the wavelength (nm).

As in 7th is also in 9 does not take into account the wavelength width until the value of the transmittance stabilizes at the point of change.

9 shows the characteristic in which the region 7b of the wavelength selection element 7 transmits 100% of the light having wavelengths shorter than 530 nm. 9 shows the characteristic in which the region 7b reflects 100% of the light with wavelengths longer than 530 nm.

The wavelength selection element 7 leaves all of the light source in the region 7b 2 emitted excitation light through.

Part of the light passing through the region 7b is used as excitation light by the luminous element 53a. Fluorescent light generated by exciting the luminous element 53a also propagates in the -Z axis direction. However, of the fluorescent light propagating in the -Z axis direction, the fluorescent light whose wavelengths are longer than 530 nm is reflected from the region 7b; the fluorescent light with wavelengths shorter than 530 nm passes through the region 7b and propagates in the -Z-axis direction.

The fluorescent light reflected from the area 7b propagates in the + Z-axis direction. Thus, excitation light emitted by the light source is converted into fluorescence light with a color temperature of 4400 K, for example, and emitted from the luminous element 53a (fluorescence generation region 53).

Here, as an example, it is assumed that the percentage of fluorescent light generated by exciting the luminous element 53a and emitted in the + Z-axis direction is 50%, and the percentage of fluorescent light emitted in the -Z-axis direction is assumed to be 50%, reflected by the wavelength selection element and propagating in the + Z-axis direction is 50%.

The percentage of fluorescent light generated by exciting the luminous element 53a and propagated in the -Z-axis direction depends on a diffusion characteristic or the like of the luminous element 53a, and therefore is not limited to 50%. Here 50% is taken as an example.

Thus the spectrum is from 470 nm to 530 nm from 8th half that of 6th .

10 Fig. 13 is a diagram illustrating an example of a wavelength characteristic of light after passing through the region 7c and emitting from the luminous element 53a. The vertical axis of 10 represents a relative light intensity (relative energy). The characteristic of 10 is normalized by the maximum light intensity. Thus the maximum value on the vertical axis is equal to "1". The horizontal axis of 10 represents the wavelength (nm).

In 10 is a spectrum from the light source 2 emitted excitation light, the curved line 30c shown in the wavelength range of 440 nm to 460 nm. A spectrum of the fluorescent light generated by exciting the luminous element 53a is the curved line 50c shown in the wavelength range from 470 nm to 780 nm.

11th FIG. 13 is a diagram showing an example of transmittance / wavelength characteristic (characteristic of transmittance with respect to wavelength) of the region 7c of the wavelength selection element 7. The vertical axis of FIG 11th represents the transmittance (%). The horizontal axis of 11th represents the wavelength l (nm).

As in 7th is also in 11th does not take into account the wavelength width until the value of the transmittance is stabilized at the point of change.

11th Fig. 7 shows the characteristic that the region 7c of the wavelength selection element 7 transmits 100% of the light having wavelengths shorter than 540 nm. 11th shows the characteristic in such a way that the region 7c reflects 100% of the light with wavelengths from 540 nm to 595 nm. 11th shows the characteristic such that the region 7c transmits 100% of the light with wavelengths longer than 595 nm.

The wavelength selection element 7 leaves all of the light source in the region 7c 2 emitted excitation light through.

Part of the light passing through the region 7c is used as excitation light by the luminous element 53a. Fluorescent light generated by exciting the luminous element 53a also propagates in the -Z axis direction. However, of the fluorescent light traveling in the Z-axis direction, the fluorescent light having wavelengths of 540 nm to 595 nm is reflected by the region 7c; the fluorescent light with wavelengths shorter than 540 nm and the fluorescent light with wavelengths longer than 595 nm pass through the region 7c and propagate in the -Z-axis direction.

The fluorescent light reflected by the area 7c propagates in the + Z-axis direction. Thus, from the light source 2 emitted excitation light is converted, for example, into fluorescence light with a color temperature of 5900 K and emitted by the luminous element 53a (fluorescence generation region 53).

Here, as an example, it is assumed that the percentage of fluorescent light generated by exciting the luminous element 53a and emitted in the + Z-axis direction is 50%, and the percentage of fluorescent light emitted in the -Z-axis direction is assumed to be reflected by the wavelength selection element 7 and propagating in the + Z-axis direction is 50%.

The percentage of fluorescent light generated by exciting the luminous element 53a and propagated in the -Z-axis direction depends on a diffusion characteristic or the like of the luminous element 53a, and therefore it is not limited to 50%. Here 50% is taken as an example.

Thus the spectrum from 470 nm to 540 nm and the spectrum from 595 nm to 780 nm are in 10 half of that in 6th .

As described above, in the configuration of the second modification, the luminous element 53a is not divided into areas. Thus, the luminous element 53a emits one type of fluorescent light. However, the division of the wavelength selection element 7 into the areas 7a, 7b and 7c enables the fluorescence generating area 53 to send light with different color temperatures to the projection lens 6th to emit.

Furthermore it is by moving the condenser lens 3 in the Y-axis direction possible to select light with different color temperatures. Here, a case in which the color temperatures are 4400 K, 5000 K and 5900 K has been described. Here, however, by considering the characteristics of the luminous element 53a or the transmittance-wavelength characteristics of the regions 7a, 7b and 7c of the wavelength selection element 7, it is possible to emit light having color temperatures different from those of the second modification. “Transmission / Wavelength Characteristic” refers to a characteristic of the transmission with respect to the wavelength.

The wavelength selection element 7 is divided into areas, thereby allowing the color temperature of light emitted from the luminous element 53 a to vary between the areas of the wavelength selection element 7. The wavelength selection element 7 is divided into areas, which can reduce the color unevenness.

Second embodiment

12th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 101 according to the second embodiment.

As in 12th As illustrated, the headlamp device 101 includes a light source 2 , a condenser lens 3 and a projection line 6th . The condenser lens 3 is provided in a wavelength selection area 12. The wavelength selection area 12 can include a fluorescence generation area 51. The fluorescence generating area 51 contains a luminous element 5 .

An example of the embodiment of the present invention will be described with reference to drawings in which a headlight device for a vehicle as in the first embodiment is taken as an example. In order to facilitate the explanation, the following description of the exemplary embodiment is given below Use of XYZ coordinates that are the same as those in the first embodiment.

The elements that are the same as those in the first embodiment are given the same reference numerals and their descriptions are omitted. The light source 2 , the fluorescence generation area 51 and the projection lens 6th are the same as those in the first embodiment. The light element 5 which is arranged in the fluorescence generation region 51 is also the same as that in the first embodiment.

The condenser lens 3 itself is the same as that in the first embodiment. Thus, the same reference number is used in the second embodiment 3 as used in the first embodiment. However, as will be described later, is the manner of moving the condenser lens 3 different from that in the first embodiment.

For the configurations, functions, operations, or the like of the elements that are the same as those in the first embodiment, even if the description thereof is omitted in the second embodiment, the description in the second embodiment is supplemented. The description regarding the first embodiment described in the second embodiment will be used as the description of the first embodiment. Here “mode of operation” includes the behavior of light.

<Light source 2>

The light source 2 emits light that serves as excitation light. The light source 2 is a light source for excitation.

As described above, the light source is 2 the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

<Wavelength selection area 12>

The wavelength selection area 12 selects wavelengths of the fluorescent light emitted by the illuminant. The wavelength selection area 12 emits the selected fluorescent light as projection light. In the example of 12th the wavelength selection area 12 contains the condenser lens 3 and the fluorescence generation area 51.

<Condenser lens 3>

The condenser lens 3 concentrated by the light source 2 emitted light.

As described above, the condenser lens is 3 even the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment. As the working of the condenser lens 3 is different from that of the first embodiment, it will be described below.

The condenser lens 3 can be pivoted about an axis S1 passing through the optical axis C. passes through and is, for example, parallel to the X-axis. The axis S1 intersects the axis C. perpendicular. In 12th the axis S1 is, for example, on an incidence surface of the condenser lens 3 . In other words, the axis S1 is a first axis that is perpendicular to the optical axis C. is.

“Pivoting” refers to swinging. For example, in 12th indicated that when viewed from the -x axis direction side, the condenser lens 3 is rotated by a predetermined angle clockwise or counterclockwise about the axis S1. Here, the predetermined angle is, for example, an angle smaller than 90 degrees. Typically, the predetermined angle is, for example, 5 degrees.

Pivoting the condenser lens 3 about the axis S1 can be the light concentration position of from the light source 2 emitted excitation light on the luminous element 5 move in the Y-axis direction.

For example, if the condenser lens 3 consists of two lenses, the two lenses are integrated. The axis S1 is located on an impingement surface of one of the two lenses on the light source side.

The axis S1 can be on an emitting surface of the condenser lens 3 condition.

<Fluorescence generation area 51>

The fluorescence generating portion 51 is the same as that in the first embodiment, and description thereof will be omitted by substituting the description in the first embodiment.

As in the case where, in the first embodiment, the condenser lens 3 is at the reference position, the area is 5a on the optical axis C. the condenser lens 3 . The area 5b is located on the + Y-axis direction side of the optical axis, for example C. . The area 5c is located on the -Y axis direction side of the optical axis, for example C. .

<Projection lens 6>

The projection lens 6th projects fluorescent light emitted from the fluorescence generation region 51 in the + Z-axis direction. The projection lens 6th projects a light distribution pattern that is at a focal position of the projection lens 6th is formed in a direction of the optical axis Zp of the projection lens 6th in the forward direction. The projection lens 6th is the same as that in the first embodiment, so description thereof will be omitted by substituting the description in the first embodiment.

<Operation of the headlamp device 101>

The operation of the headlamp device 101 will now be described.

When the condenser lens 3 is pivoted about the axis S1 counterclockwise when viewed from the -X axis direction side, plants from the condenser lens 3 emitted light while inclined in the + Y-axis direction. Thus, the condenser lens 3 the excitation light on the area 5b of the light element 5 focus. Pivoting the condenser lens 3 about the axis S1 counterclockwise when viewed from the -X axis direction side is called "pivoting the condenser lens 3 in the + Y-axis direction ”.

When the condenser lens 3 is panned clockwise when viewed from the -X axis direction side, plants off the condenser lens 3 emitted light while being inclined in the -Y axis direction. Thus, the condenser lens 3 the excitation light on the area 5c of the light element 5 focus. Pivoting the condenser lens 3 clockwise about the axis 51 when viewed from the -X axis direction side is called "pivoting the condenser lens 3 in the -Y-axis direction “.

The swivel angle is a function of the light concentration position on the luminous element 5 set.

When the central axis S1 of the pivot is on the side of the emitting surface of the capacitor 3 the position of the optical axis moves C. on the impact surface of the condenser lens 3 in a direction opposite to a direction of rotation of the condenser lens 3 in the Y-axis direction.

Thus, in a case where the central axis S1 is planted on the emitting surface side of the condenser lens, for example 3 located when the condenser lens 3 counterclockwise when viewed from the -X axis direction side, from the condenser lens 3 emitted light while being inclined in the -Y axis direction. When the condenser lens 3 is pivoted about the axis S1 in the clockwise direction when viewed from the -X axis direction side, it is planted from the condenser lens 3 emitted light continues while being tilted in the + Y-axis direction.

The operation shown when the central axis S1 of the pivot is on the emitting surface side of the condenser lens 3 is different from the operation shown when the central axis S1 is on the incident surface side of the condenser lens 3 is located.

When the central axis S1 of the pivot is on the side of the incidence surface of the condenser lens 3 is the position of the optical axis C. on the impact surface of the condenser lens 3 stationary, with only pivoting the condenser lens 3 influences the light beam direction, and an effect on the light beam aberration is small. Thus, it is preferable that the central axis S1 of the pivot is on the side of the incidence surface of the condenser lens 3 is located. Depending on the use, structural constraints, or the like, the central axis S1 may be on the emitting surface side of the condenser lens 3 be arranged.

From the areas 5b and 5c emitted light rays are not on the optical axis Cp of the projection lens 6th . Thus, typically from the areas 5b and 5c emitted light rays obliquely to the optical axis Cp after passing through the projection lens 6th have passed through. That is, from the areas 5b and 5c emitted light rays are after passing through the projection lens 6th not parallel to the optical axis Cp. In the second embodiment, the optical axis Cp of the projection lens is correct 6th with the optical axis C. the condenser lens 3 as in the first embodiment.

However, as described in the first embodiment, by increasing the distance from the luminous element 5 to the projection lens 6th the positions of the light beams are arranged at an irradiation position so that there is no problem in practical use. Even if the luminous element 5 in the three areas 5a , 5b and 5c is divided by each of the areas 5a , 5b and 5c light emitted through the projection lens 6th to an extent in to that optical Cp converted to parallel light that there is no problem in practical use.

On the other hand, if the direction of the projected light is positively changed, the distance from the luminous element can 5 to the projection lens 6th be made small. By continuously or stepwise changing the distance from the luminous element 5 to the projection lens 6th the amount of change in the light distribution direction can be changed.

The fluorescence generating portion 52 described in the first embodiment can be applied to the second embodiment, and the same effect can be obtained.

With the above operation, if the optical axis C. the condenser lens 3 with the optical axis Cp of the projection lens 6th in the Y-axis direction from the light source 2 emitted excitation light on the area 5a of the light element 5 concentrated. When the optical axis C. the condenser lens 3 in the + Y-axis direction with respect to the optical axis Cp of the projection lens 6th is pivoted is from the light source 2 emitted excitation light on the area 5b of the light element 5 concentrated. When the optical axis C. the condenser lens 3 in the -Y axis direction with respect to the optical axis Cp of the projection lens 6th is pivoted is from the light source 2 emitted excitation light on the area 5c of the light element 5 concentrated.

Thus it is by pivoting the condenser lens 3 about the axis S1 possible, the light concentration position on the luminous element 5 to move. This makes it possible to switch between the three color temperatures. Further, as in the first embodiment, the provision of a space or the like between each area prevents mixing of light beams having different color temperatures, thereby occurrence of color unevenness from the projection lens 6th emitted light is prevented.

The number of areas of the luminous element 5 is not limited and can be two or four. The distance between the light element 5 and the projection lens 6th is such that light rays are obtained which do not pose a problem in terms of parallelism in practical use. Thus, in particular, there is the luminous element 5 is always on the optical axis Cp through the projection lens 6th transmitted light parallel to the optical axis Cp.

The fluorescence generating regions 52 and 53 of the first and second modifications described in the first embodiment can be used in the second embodiment, and the same effects can be obtained.

Third embodiment

13th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 102 according to the third embodiment of the present invention.

As in 13th As illustrated, the headlamp device 102 includes a light source 2 , a wavelength selection section 13 and a projection lens 6th . The wavelength selection area 13 includes a condenser lens 3 and a fluorescence generation area 54. The fluorescence generation area 54 contains a luminous element 5 .

An example of the embodiment of the present invention will be described with reference to drawings by taking as an example a headlight device for a vehicle as in the first embodiment. In order to facilitate the explanation, the embodiment will be described below using XYZ coordinates that are the same as those in the first embodiment.

Elements that are the same as those in the first embodiment are given the same reference numerals and their descriptions are omitted. The light source 2 and the projection lens 6th are the same as those in the first embodiment.

The fluorescence generation area 54 differs from the fluorescence generation area 51 according to the first exemplary embodiment, but the luminous element arranged in the fluorescence generation area 54 5 itself is the same as that in the first embodiment. Thus, in the third embodiment, the reference number becomes 5 as used in the first embodiment. However, as will be described later, different from the first embodiment, the luminous element becomes 5 kept moveable.

The condenser lens 3 itself is the same as that in the first embodiment. Thus, in the third embodiment, the reference number becomes 3 as used in the first embodiment. However, as will be described later, different from the first embodiment is the condenser lens 3 fixed. For example, is the condenser lens 3 in a direction perpendicular to the optical axis C. fixed; or the condenser lens 3 is in a direction of rotation about one to the optical axis C. fixed vertical axis.

For the configurations, functions, operations, or the like of the elements that are the same as those in the first or second embodiment, even if their descriptions are omitted in the third embodiment, the description is applied to the first or second embodiment. The description regarding the first or second embodiment described in the third embodiment will be used as a description of the first embodiment. Here “mode of operation” includes the behavior of light.

<Light source 2>

The light source 2 emits light that serves as excitation light. The light source 2 is a light source for excitation.

As described above, the light source is 2 the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

<Wavelength selection area 13>

The wavelength selection section 13 selects wavelengths of fluorescent light emitted from the phosphor. The wavelength selection area 13 emits the selected fluorescent light as projection light. In the example of 13th the wavelength selection area 13 contains the condenser lens 3 and the fluorescence generation area 54.

<Condenser lens 3>

The condenser 3 concentrated by the light source 2 emitted light.

As described above, the condenser lens is 3 even the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

<Fluorescence generation area 54>

The fluorescence generating area 54 contains the luminous element 5 which is the same as that in the first embodiment. Thus, for the luminous element 5 even a description thereof is omitted by substituting the description in the first embodiment.

The light element 5 can extend in a direction perpendicular to the optical axis C. move. For example, in 13th the direction perpendicular to the optical C is the Y-axis direction.

For example, the position of the lighting element 5 , on which a central axis of the luminous element 5 with the optical axis C. the condenser lens 3 coincides as a reference position of the luminous element 5 taken. The reference position of the light element 5 is a position where the area 5a on the optical axis C. is.

In the first and second embodiments, the light concentration position of the excitation light is on the luminous element 5 by moving the condenser lens 3 postponed. On the other hand, in the third embodiment, the light concentration position of the excitation light is on the luminous element 5 by moving the phosphor element 5 shifted while the condenser lens is fixed. The third embodiment differs from the first and second embodiments in this point.

In the first and second embodiments, the condenser lens is 3 relative to the luminous element 5 emotional. On the other hand, in the third embodiment, the luminous element 5 relative to the condenser lens 3 emotional.

<Projection lens 6>

The projection lens 6th projects fluorescent light emitted from the fluorescence generation region 54 in the + Z-axis direction. The projection lens 6th projects a at a focal position of the projection lens 6th light distribution pattern formed in a direction of the optical axis Cp of the projection lens 6th in the forward direction. The projection lens 6th is the same as that in the first embodiment, so description thereof will be omitted by substituting the description in the first embodiment.

<Operation of the headlamp device 102>

The operation of the headlamp device 102 will now be described.

The light element 5 is shifted in the Y-axis direction, for example.

When the luminous element 5 in the + Y-axis direction is shifted by the condenser lens 3 emitted light on the area 5c concentrated.

When the luminous element 5 is shifted in the -Y-axis direction is by the condenser lens 3 emitted light on the area 5b concentrated.

When the luminous element 5 is not shifted from the reference position, is by the condenser lens 3 emitted light on the area 5a concentrated. That is, if the luminous element 5 is at the reference position is taken from the condenser lens 3 emitted light on the area 5a concentrated.

The amount of displacement of the luminous element 5 in the Y-axis direction is set so that the areas 5a , 5b and 5c of the light element 5 on the optical axis C. are.

From the areas 5a , 5b and 5c emitted light rays are on the optical axis Cp of the projection lens 6th . Thus, the light rays are parallel to the optical axis Cp after passing through the projection lens 6th have passed through.

Thus, there are restriction conditions such as increasing the distance from the phosphor element 5 to the projection lens 6th facilitated.

As described in the first and second embodiments, in the first and second embodiments of the projection lens 6th emitted light not exactly parallel to the optical axis Cp. However, in the third embodiment, is from the projection lens 6th emitted light parallel to the optical axis Cp.

The first and second modifications described in the first embodiment can be applied to the third embodiment, and the same effects can be obtained.

That is, the combination of the wavelength selection element 700 and the luminous element 5 in the fluorescence generation region 52 can in the luminous element 5 can be applied according to the third embodiment. The combination of the wavelength selection element 7 and the luminous element 53a in the fluorescence generation region 53 can be used in the luminous element 5 can be applied according to the third embodiment.

With the above operation, when the luminous element 5 is at the reference position and the area 5a on the optical axis C. is, from the light source 2 emitted excitation light on the area 5a concentrated. When the luminous element 5 is shifted from the reference position in the + Y-axis direction and the area 5c on the optical axis C. is, is from the light source 2 emitted excitation light on the area 5c concentrated. When the luminous element 5 is moved out of the reference position in the -Y axis direction and the area 5b on the optical axis C. is, is from the light source 2 emitted excitation light on the area 5b concentrated.

By moving the light element 5 in the Y-axis direction with respect to the optical axis C. it is possible to use the area on the luminous element 5 , to that of the condenser lens 3 emitted excitation light is concentrated between the areas 5a , 5b and 5c to change. This enables you to switch between the three color temperatures. Furthermore, mixing of light rays having different color temperatures does not occur, and thus the occurrence of color unevenness from the projection lens becomes 6th prevents emitted light.

The number of areas of the luminous element 5 is not limited, and can be two or more. In particular, there is the luminous element 5 is always on the optical axis Cp, light after passing through the projection lens 6th parallel to the optical axis Cp.

Fourth embodiment

14th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 103 according to the fourth embodiment of the present invention.

As in 14th As illustrated, the headlamp device 103 includes a light source 2 , a condenser lens 3 , a transmission element 4th and a projection lens 6th . The headlight device 103 may include a fluorescence generation area 51. The fluorescence generating area 51 contains a luminous element 5 . The fluorescence generation area 51 is arranged in a wavelength selection area 14. The condenser lens 3 and the transmission element 4th are also arranged in the wavelength selection area 14.

An example of the embodiment according to the present invention will be described with reference to drawings by taking as an example a headlight device for a vehicle as in the first embodiment. In order to facilitate the explanation, the embodiment will be described below using XYZ coordinates which are the same as those in the first embodiment.

Elements that are the same as those in the first embodiment are given the same reference numerals, and the description thereof is omitted. The light source 2 , the fluorescence generation area 51 and the projection lens 6th are the same as those in the first embodiment.

The luminous element arranged in the fluorescence generating region 51 5 is also the same as that in the first embodiment.

The condenser lens 3 itself is the same as that in the first embodiment. Thus, in the third embodiment, the reference number becomes 3 as used in the first embodiment. However, as will be described later, different from the first embodiment is the condenser lens 3 fixed. The condenser lens 3 is fixed as in the third embodiment.

For the configurations, functions, operations, or the like of elements that are the same as those of any one of the first to third embodiments, even if their descriptions are omitted in the fourth embodiment, the descriptions in the first to third embodiments are employed. Descriptions regarding the first to third embodiments described in the fourth embodiment are used as descriptions of the first to third embodiments, respectively. Here “mode of operation” includes the behavior of light.

<Light source 2>

The light source 2 emits light that serves as excitation light. The light source 2 is a light source for excitation.

As described above, the light source is the same as that in the first embodiment, so description thereof will be omitted by substituting the description in the first embodiment.

<Wavelength selection area 14>

The wavelength selection section 14 selects wavelengths of the fluorescent light emitted from the phosphor. The wavelength selection area 14 emits the selected fluorescent light as projection light. In the example of 14th the wavelength selection area 14 contains the condenser lens, the transmission element 4th and the fluorescence generation area 51.

<Condenser lens 3>

The condenser lens 3 concentrated by the light source 2 emitted light.

As described above, the condenser lens is 3 even the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment. The condenser lens 3 is relative to the light source 2 fixed as in the third embodiment.

<Transmission element 4>

The transmission element 4th changes the direction of propagation from from the condenser lens 3 emitted excitation light.

The transmission element 4th is for example a plate-like optical element. In the fourth embodiment, the transmission element 4th described as a parallel plate. A transmission member having a light incident surface and a light emitting surface inclined with respect to the light incident surface can be used.

The transmission element 4th is pivoted about an axis S2 parallel to the X-axis. For example, in 14th as viewed from the -X axis direction side, the transmission member 4th be pivoted by a predetermined angle clockwise or counterclockwise about the axis S2. In other words, the axis S2 is a second axis perpendicular to the optical axis C. .

In 14th the axis S2 intersects the optical axis, for example C. orthogonal "orthogonal cutting" refers to cutting at a right angle. In 14th When viewed in the X-axis direction, the axis S2 is on the optical axis C. .

In 14th the axis S2 is on an impact surface of the transmission element 4th . However, it can be on an emitting surface of the transmission element 4th condition.

The material of the transmission element 4th is for example glass with a refractive index of 1.52. It is not limited to glass and can be any refractive material. However, it has a high transmittance for the sake of light utilization efficiency

<Fluorescence generation area 51>

The fluorescence generating portion 51 is the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

As in the case where the condenser lens 3 in the first embodiment is at the reference position, the area is 5a on the optical axis C. the condenser lens 3 . The area 5b is for example on the + Y-axis direction side of the optical axis C. . The area 5c is located on the -Y axis direction side of the optical axis, for example C. . The reference position of the condenser lens 3 in the first embodiment, the position is in the state in which the condenser lens 3 is not pivoted in the first embodiment.

<Projection lens 6>

The projection lens 6th projected from the luminous element 5 fluorescent light emitted in the + Z-axis direction. The projection lens 6th is the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

<Operation of the headlamp device 103>

The operation of the headlamp device 103 will now be described.

the 15a , 15b and 15c are results of a light beam tracking simulation for explaining the operation of the headlamp device 103 according to the fourth embodiment

In 15A is the transmission element 4th perpendicular to the optical axis C. .

In 15B is the transmission element 4th when viewed from the -X-axis direction side counterclockwise from the state of 15A panned.

In 15C is the transmission element 4th when viewed from the -X-axis direction side clockwise from the state of 15A panned.

In the 15B and 15C the pivot angle is, for example, 30 degrees in each case.

the 15A , 15B and 15C show different optical paths. The rays of light in 15A are referred to as the light rays 300a. The rays of light in 15B are referred to as the light rays 300b. The rays of light in 15C are referred to as the light rays 300c. the 15A , 15B and 15C point from a center of the light source 2 emitted light beams 300a, 300b and 300c.

From the light source 2 emitted light plants in the + Z-axis direction with one on the optical axis C. centered emission angle.

The light propagating in the + Z-axis direction hits the condenser lens 3 on.

That on the condenser lens 3 incident light is concentrated.

In the case of 15A is an impact surface 41 of the transmission element 4th perpendicular to the optical axis C. . From the light beams 300a, the light beam is planted on the optical axis C. without being broken at the impact surface 41. Thus, the light concentration position of the light beams 300a is on the optical axis C. . In 15A the light rays 300a on the area 5a of the light element 5 concentrated.

In the case of 15B is the impact surface 41 of the transmission element 4th with respect to the optical axis C. rotated 30 degrees counterclockwise when viewed from the -X axis direction side. Of the light beams 300b, the light beam becomes on the optical axis C. is broken at the landing surface 41 in the + Y-axis direction and propagates. Thus, the light concentration position of the light beams is 300b with respect to the optical axis C. shifted in the + Y-axis direction. In 15B the light rays 300b become on the area 5b of the light element 5 concentrated.

In the case of 15C is the impact surface 41 of the transmission element 4th with respect to the optical axis C. rotated 30 degrees clockwise when viewed from the -X axis direction side. Of the light beams 300c, the light beam becomes on the optical axis C. is broken at the landing surface 41 in the -Y axis direction and propagates. Thus, the light concentration position of the light beams 300c is in the -Y axis direction with respect to the optical axis C. postponed. In 15C the light rays 300c on the area 5c of the light element 5 concentrated.

By the above-described operation, when the impact surface 41 of the transmission element 4th perpendicular to the optical axis C. is that of the light source 2 emitted light rays 300a on the area 5a of the light element 5 concentrated. When the impact surface 41 of the transmission element 4th with respect to the optical axis C. is panned counterclockwise when viewed from the -X-axis direction side, the from the light source 2 emitted light beams 300b onto the area 5b of the light element 5 concentrated. When the impact surface 41 of the transmission element 4th with respect to the optical axis C. is panned clockwise when viewed from the -X-axis direction side, the from the light source 2 emitted light beams 300c on the area 5c of the phosphor element 5 concentrated.

By pivoting the transmission element 4th it is possible to know the light concentration position from from the condenser lens 3 emitted excitation light on the luminous element 5 to move. This enables you to switch between three color temperatures. Furthermore, mixing of light rays having different color temperatures does not occur, and thus the occurrence of color unevenness of the projection lens becomes 6th prevents emitted light.

The optimal swivel angle for concentrating light on the respective areas 5a , 5b and 5c of the light element 5 depend on the thickness or the refractive index of the transmission element 4th away. The optimal swivel angles for concentrating light also depend on the respective areas 5a , 5b and 5c of the light element 5 of the locations of the areas 5a , 5b and 5c away.

In the above description, the light beams 300a, 300b and 300c are applied to the areas, respectively 5a , 5b and 5c of the light element 5 concentrated. However, the light concentration positions of the light beams 300a, 300b, and 300c do not necessarily need to be on the luminous element 5 to be. That is, the light concentration positions of the light beams 300a, 300b, and 300c may be in a direction of the optical axis C. with reference to the luminous element 5 be postponed. It is sufficient that light bundles of the light beams 300a, 300b and 300c are respectively in the areas 5a , 5b and 5c arrive. That is, it is sufficient that the spot diameters of the light beams 300a, 300b, and 300c are in the ranges, respectively 5a , 5b and 5c fall.

Advantages of the fourth embodiment will now be described.

By adjusting the pivot angle of the transmission element 4th it is possible to get light with different color temperatures from the projection lens 6th to emit. Furthermore, mixing of light rays of different colors does not occur, and thus color temperature unevenness can be reduced. It can be achieved by the simple operation of pivoting the transmission member 4th can be implemented to facilitate the downsizing of the apparatus. Furthermore, since the operation is simple, the drive mechanism can be easily simplified, and the cost can be reduced due to the reduction in the number of parts or the simplification of assembly.

From the foregoing, it is possible to provide a headlamp device that can display various color temperatures by adjusting the pivoting angle of the transmission member 4th and the appearance of color unevenness of the projection lens 6th emitted light can be prevented.

The position of the transmission element 4th is preferably between the condenser lens 3 and the light element 5 . The one from the light source 2 emitted light beams 300a, 300b and 300c are passed through the condenser lens 3 concentrated. Thus, the transmission element 4th can be implemented by a small component.

The first or second modification described in the first embodiment can be applied to the fourth embodiment, and the same effects can be obtained.

That is, the combination of the wavelength selection element 700 and the luminous element 5 in the fluorescence generation region 52 can in the luminous element 5 can be applied according to the fourth embodiment. The combination of the wavelength selection element 7 and the luminous element 53a in the fluorescence generation region 53 can be applied to the luminous element 5 can be applied according to the fourth embodiment.

17th illustrates a configuration in which a condenser lens 3b is interposed between a transmission element 4th and a luminous element 502 is arranged. 17th FIG. 13 is a configuration diagram of a headlight device 104 schematically illustrating an exemplary configuration in which parallel light is incident on the transmission member 4th hits.

The headlamp device 104 includes a collimator lens 3a between a light source 2 and the transmission element 4th . the headlamp device 104 also includes the condenser lens 3b between the transmission element 4th and the luminous element 502.

The collimator lens 3a directs from the light source 2 emitted light into parallel light. The condenser lens 3b concentrates parallel light passing through the transmission element 4th passes through.

In this case it is from the light source 2 emitted light is directed parallel by the collimator lens 3a and reaches the transmission element 4th . Then, the parallel light emitted from the collimator lens 3a becomes in the Y-axis direction depending on a pivoting of the transmission member 4th shifted about an axis S2 and reaches the condenser lens 3b.

The condenser lens 3b concentrates the incident parallel light on the optical axis C. the condenser lens 3b. Thus become regardless of a pivoting of the transmission element 4th Light beams 300a, 300b and 300c on the optical axis C. concentrated. Thus, it is not possible to cause the light beams 300b to enter the area 5b reach. Also, it is not possible to make the light rays 300c clear the area 5c reach. It is not possible to change the color temperature of light projected from the headlight device.

Fifth embodiment

18th Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 104a according to the fifth embodiment of the present invention.

As in 18th As illustrated, the headlamp device 104a includes a light source 2 , a wavelength selection area 15 and a projection lens 6th . The wavelength selection area 15 includes a condenser lens 3 and a fluorescence generation area 55. The fluorescence generation area 55 includes a luminous element 540. The fluorescence generation area 55 may include a wavelength selection element 710.

An example of the embodiment according to the present invention will be described with reference to drawings by taking as an example a headlight device for a vehicle as in the first embodiment. In order to simplify the explanation, the following description of the embodiment will be made using XYZ coordinates which are the same as those in the first embodiment.

Elements that are the same as those in the first embodiment are given the same reference numerals and descriptions thereof are omitted. The light source 2 and the projection lens 6th are the same as those in the first embodiment.

The condenser lens 3 itself is the same as that in the first embodiment. Thus, in the fifth embodiment, the reference numeral becomes 3 as used in the first embodiment. However, as will be described later, different from the first embodiment is the condenser lens 3 fixed. As with the third embodiment, the condenser lens is 3 fixed.

For the configurations, functions, operations, or the like of elements that are the same as those of any one of the first to fourth embodiments, even if their descriptions are omitted in the fifth embodiment, the description in the first to fourth embodiments is employed. Descriptions regarding the first to fourth embodiments described in the fifth embodiment will be used as descriptions of the first to fourth embodiments. Here “mode of operation” includes the behavior of light.

<Light source 2>

The light source 2 emits light that serves as excitation light. The light source 2 is a light source for excitation.

As described above, the light source is 2 the same as that in the first embodiment, so a description thereof will be omitted by substituting the description in the first embodiment.

<Wavelength selection area 15>

The wavelength selection section 15 selects wavelengths of fluorescent light emitted from the phosphor. The wavelength selection area 15 emits the selected fluorescent light as projection light. The wavelength selection area 15 contains the condenser lens 3 and the fluorescence generation area 55.

<Condenser lens 3>

The condenser lens 3 condensed from the light source 2 emitted light.

As described above, the condenser lens is 3 even the same as that in the first embodiment, so a description thereof will be omitted by substituting the description of the first embodiment. The condenser lens 3 is relative to the light source 2 fixed as in the third embodiment.

As in the case where the condenser lens 3 in the first embodiment is at the reference position, the optical axis is correct C. the condenser lens 3 with the optical axis Cp of the projection lens 6th match.

<Fluorescence generation area 55>

The fluorescence generation area 55 includes the wavelength selection element 710 and the luminous element 540.

The wavelength selection element 710 and the luminous element 540 pivot about an axis 53. The axis S3 is, for example, parallel to the Z axis. That is, the axis S3 is, for example parallel to the optical axis C. . The axis S3 is, for example, parallel to the optical axis Cp.

The wavelength selection element 710 is on the side of the condenser lens 3 from the luminous element 540. The luminous element 540 is located on the + Z-axis direction side of the wavelength selection element 710. The luminous element 540 is located on the projection lens side 6th from the wavelength selection element 710.

The wavelength selection element 710 contains, for example, a glass substrate with a coating applied thereon with a wavelength selection characteristic.

The luminous element 540 is applied, for example, to a light incident surface side or a side of a light-emitting surface of the wavelength selection element 710. The luminous element 540 is applied concentrically, for example.

In 18th the wavelength selection element 710 is integrated with the luminous element 540.

19th Fig. 13 is a schematic diagram of the wavelength selection element 710 and the luminous element 540 according to the fifth embodiment. 19th FIG. 13 is a diagram of the wavelength selection element 710 and the luminous element 540 viewed from the + Z axis side.

The luminous element 540 is divided into three areas in a circumferential direction, for example, as in FIG 19th is illustrated.

For example, the luminous element 540 contains areas 540a, 540b and 540c. The luminous element 540 contains the areas 540a, 540b and 540c which are divided radially about the axis S3. The areas 540a, 540b and 540c have fan shapes. Mean angles of the fan shapes are, for example, 120 degrees.

The area 540a emits fluorescent light with a color temperature of, for example, 6000 K. The area 540b emits fluorescent light with a color temperature of, for example, 4000 K. The area 540c emits fluorescent light with a color temperature of, for example, 2500 K.

The areas 540a, 540b and 540c are arranged so that each of the areas 540a, 540b, 540c due to the rotation thereof on the optical axis C. is located. The luminous element 540 is rotated such that the areas 540a, 540b and 540c are on the optical axis C. condition.

As a result, the luminous element 540 can emit fluorescent light of different wavelengths. It differs from the first embodiment in this point.

The number of areas of the luminous element 540 is not limited and may be two or four. In particular, the luminous element 540 is always arranged on the optical axis Cp. Thus, after it is through the projection lens 6th has passed, fluorescent light emitted from the luminous element 540 is light parallel to the optical axis Cp.

Thus, light emitted from areas 540a, 540b and 540c is after passing through the projection lens 6th light parallel to the optical axis Cp.

The diameter of the concentrated light on the luminous element 540 is 0.5 mm, for example.

The fifth exemplary embodiment also contains the wavelength selection element 710. The luminous element 540 is applied to the wavelength selection element 710. However, the luminous element 540 may be applied to a glass substrate that does not have a wavelength selection characteristic.

<Projection lens 6>

The projection lens 6th projects fluorescent light emitted from the fluorescence generation region 55 in the + Z-axis direction. The projection lens 6th is the same as that in the first embodiment, so description thereof will be omitted by substituting the description of the first embodiment.

<Operation of the headlamp device 104a>

The operation of the headlamp device 104a will now be described.

The luminous element 540 rotates about the axis S3. The axis S3 is, for example, parallel to the optical axis C. .

When the area 540a of the luminous element 540 is on the optical axis C. is located by the condenser lens 3 Emitted light is concentrated on the area 540a. When the area 540b of the luminous element 540 is on the optical axis C. is located, this is determined by the condenser lens 3 emitted light is concentrated on the area 540b. When the area 540c of the luminous element 540 is on the optical axis C. is located by the Condenser line 30 concentrated light emitted on the area 540c.

The angle of rotation of the luminous element 540 is set such that the areas 540a, 540b and 540 of the luminous element 540 are on the optical axis C. condition.

Light emitted from the areas 540a, 540b and 540c is on the optical axis Cp. Thus, rays of light are after passing through the projection lens 6th parallel to the optical axis Cp.

Thus, restriction conditions such as an increase in the distance from the luminous element 540 to the projection lens become 6th facilitated.

By the above-described operation, when the area 540a of the luminous element 540 is on the optical axis C. from the light source 2 emitted excitation light is concentrated on the area 540a. When the area 540b of the luminous element 540 is on the optical axis C. is located by the light source 2 emitted excitation light is concentrated on the area 540b. When the area 540c of the luminous element 540 is located on the optical C, the light source 2 emitted excitation light is concentrated on the area 540c.

By rotating the luminous element 540 about the axis S3, it is possible to adjust the area of the optical axis C. of the luminous element 540 between the areas 540a, 540b and 540c and from the condenser lens 3 to concentrate emitted excitation light on this.

This enables you to switch between the three color temperatures. Furthermore, mixing of light rays having different color temperatures does not occur, and thus color unevenness of the projection lens may occur 6th emitted light can be prevented.

<Third modification>

20th Fig. 13 is a schematic diagram of a wavelength selection element 711 and a luminous element 550 according to a third modification. 20th Fig. 13 is a diagram of the wavelength selection element 711 and the luminous element 550 viewed from the + Z axis side. Since only the wavelength selection element 711 and the luminous element 550 in the fluorescence generation region 55 are different from those of the FIG 18th illustrated headlight device 104a are different, only the differences from that in FIG 18th illustrated headlight device 104a described.

The fluorescence generation area 55 contains the wavelength selection element 711 instead of the wavelength selection element 710. Furthermore, the fluorescence generation area 55 contains the luminous element 550 instead of the luminous element 540.

The wavelength selection element 711 and the luminous element 550 rotate about the axis 53. The axis S3 is, for example, parallel to the Z-axis. That is, the axis S3 is parallel to the optical axis, for example C. . The axis S3 is, for example, parallel to the optical axis Cp.

The luminous element 550 is located on the + Z-axis direction side of the wavelength selection element 711.

The wavelength selection element 711 contains, for example, a glass substrate to which a coating having a wavelength selection characteristic is applied. The coating with the wavelength selection characteristic can be applied to the + Z-axis side or the -Z-axis side of the wavelength selection element 711.

Areas 711a, 711b and 711c may have the same wavelength selection characteristics as the areas 7a, 7b and 7c described in the second modification of the first embodiment. This makes it possible to emit light having the same wavelengths as those in the second modification of the first embodiment.

The luminous element 550 is applied to a light incident surface side of the wavelength selection element 711, for example. That is, the luminous element 550 is applied to a surface on the + Z-axis direction side of the wavelength selection element 711. In 20th the luminous element 550 is applied to the wavelength selection element 711 concentrically with respect to the axis 53.

In 20th For example, the luminous element 550 is directly applied to the surface on the + Z-axis direction side of the wavelength selection element 711. The wavelength selection element 711 is thus integrated with the luminous element 550.

In the third modification, the luminous element 550 is formed by a single phosphor.

The wavelength selection element 711 is divided into the areas 711a, 711b and 711c.

The wavelength selection element 711 is divided into the three areas in a circumferential direction, for example, as in FIG 20th is illustrated.

For example, the wavelength selection element 711 contains the regions 711a, 711b and 711c which are divided radially about the axis S3. The areas 711a, 711b and 711c have fan shapes. The mean angles are, for example, 120 degrees.

By rotating the wavelength selection element 711 about the axis S3, it is possible to select the one on the optical axis C. change the area located between areas 711a, 711b and 711c.

When the configuration described in the fifth embodiment is used, it is possible to have time division control in connection with the light source 2 perform.

That is, when any of the areas 540a, 540b, and 540c are on the optical axis C. is arranged, light is from the light source 2 emitted. In the third modification, when any one of the areas 711a, 711b and 711c is on the optical axis C. located, light from the light source 2 emitted.

With the configuration described in the fifth embodiment, it is possible to cause light of different wavelengths emitted from the areas 540a, 540b, and 540c to be applied to the projection lens in a time-division manner 6th hits. In the configuration described in the third modification, it is possible to cause lights of different wavelengths emitted from the areas 711a, 711b, and 711c to be applied to the projection lens in a time-division manner 6th hits.

“Time sharing” refers to performing two or more processes alternately at different times in a single device. Here, the fluorescence generation region 55 can cause light of different wavelengths to be incident on the projection lens at different times 6th hits.

This makes it possible to project light beams with several color temperatures. A central ray of light one on the projection lens 6th The incident light beam is located on the optical axis Cp. Thus, light with high parallelism with respect to the optical axis Cp can be emitted from the projection lens 6th are emitted. Here, “medium light beam” refers to a light beam that is on the optical axis C. the condenser lens 3 propagates.

In the third modification, a case where the wavelength selection element 711 is divided into three has been described. However, it does not necessarily have to be divided into three, and may be divided into two, four, or more.

Sixth embodiment

21 Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 105 according to a sixth embodiment of the present invention.

As in 21 As illustrated, the headlamp device 105 includes a light source 2 , a condenser lens 3 , a transmission element 4th and a projection lens 6th . The headlight device 105 may include a lighting element 560. The headlamp device 105 may include a fluorescence generation area 56. The fluorescence generating area 56 contains the luminous element 560. The headlight device 105 does not contain a wavelength selection area. Thus, the headlamp device 105 cannot change the wavelength of the projection light.

An example of the embodiment of the present invention will be described with reference to drawings by taking as an example a headlight device for a vehicle as in the first embodiment. In order to facilitate the explanation, the embodiment will be described below using XYZ coordinates which are the same as those in the first embodiment.

Elements that are the same as those in the first embodiment are given the same reference numerals and descriptions thereof are omitted. The light source 2 and the projection lens 6th are the same as those in the first embodiment.

The condenser lens 3 itself is the same as that in the first embodiment. Thus, in the sixth embodiment, the reference numeral becomes 3 as used in the first embodiment. However, as will be described later, the condenser lens is different from the first embodiment 3 fixed.

The transmission element 4th is the same as the transmission element described in the fourth embodiment 4th . Thus, description overlapping with the description of the fourth embodiment is omitted in the sixth embodiment by substituting the description of the fourth embodiment.

For the configurations, functions, operations, or the like of elements that make up the are the same as those of any one of the first to fifth embodiments, even if their description is omitted in the sixth embodiment, the description is employed in the first to fourth embodiments. Descriptions regarding the first to fifth embodiments described in the sixth embodiment will be used as descriptions of the first to fifth embodiments. Here “mode of operation” includes the behavior of light.

As in 21 As illustrated, the lighting element 560 of the headlight device 105 is formed by a single phosphor. The headlight device 105 differs from the headlight device 103 according to the fourth exemplary embodiment in that it has the light-emitting element 560 instead of the light-emitting element 5 has.

The headlight device 105 according to 21 shifts the light concentration position on the luminous element 560 from the light source 2 emitted light in the Y-axis direction by pivoting the transmission member 4th about the axis S2 as in the fourth embodiment.

The effects of the sixth embodiment will be described.

16 is used as a light ray tracing diagram for explaining the effects of the sixth embodiment. The explanation is made on the assumption that the luminous element 5 in 16 is the luminous element 560.

The luminous element 560 consists of a single area. Thus the areas emit 5a , 5b and 5c Rays of light in the same wavelength band.

From the area 5a emitted light rays 1400a propagate parallel to the optical axis Cp after passing through the projection lens 6th have passed through. From the area 5b emitted light rays 1400b propagate in the -Y-axis direction obliquely to the optical axis Cp after passing through the projection lens 6th have passed through. From the area 5c emitted light rays 1400c propagate in the + Y-axis direction obliquely to the optical axis Cp after passing through the projection lens 6th have passed through.

Thus, by controlling the position at which light beams are emitted from the luminous element 560, it is possible to control the direction in which the light beams travel. By changing the light emitting area of the luminous element 560 between the areas 5a , 5b and 5c it is possible to control the position irradiated by light.

For example, when a driver is cornering, the headlight device 105 may be from the light source 2 project emitted light in the direction of travel of the vehicle. The direction of travel of the vehicle is a direction in which the vehicle turns. This enables the driver's visibility with respect to the direction of travel of the vehicle to be improved.

The headlamp device 105 can shift the position irradiated by light with a simple configuration. The headlamp device 105 can control the light distribution.

With this configuration, the headlamp device 105 can be used as an adaptive front lighting system (AFS). The AFS is a variable light distribution headlamp that detects a steering angle, vehicle speed or the like when turning a road at night and directs the irradiation direction of the headlamp into the turning direction.

The headlamp device 105 can light distribution with a simple configuration in which the transmission member 4th is panned, change. Furthermore, it enables the headlight device 105 to be the transmission element 4th pivots so that a headlight with variable light distribution can be reduced in size.

For example, the headlight device 105 can be the transmission element 4th to continuously pan in the left-right direction in a reciprocating manner. When a person is present in the forward direction, the headlamp device 105 can be the transmission element 4th Pan so as to avoid an area where the person is present and project light. The headlight device 105 can also be the light source 2 switch off when the projected light reaches the area in which the person is present.

With this configuration, the headlamp device 105 can be used as an adaptive driving beam (ADB). The ADB is a headlight system that, when a vehicle in front appears like an oncoming vehicle or a vehicle in front while driving with high beam, detects the position of the vehicle in front using an in-vehicle camera, shading only the area and the other area with high beam irradiated. Furthermore, the headlamp device 105 can control the light distribution in a direction according to a curve of a road by adjusting the Pivot angle of the transmission element 4th . Furthermore, the headlamp device 105 can control the light distribution according to the width of a road by adjusting the pivot angle of the transmission member 4th .

For example, in a narrow road, the pivot angle of the transmission member becomes 4th made narrow. On the other hand, on a wide road, the pivot angle of the transmission member becomes 4th made far. This makes it possible to control the light distribution according to the width of a road. By continuously changing the pivot angle of the transmission element 4th it is possible to provide a light distribution corresponding to the width of a street.

In the sixth embodiment, achieved by the condenser lens 3 emitted light the transmission element 4th . The transmission element 4th is pivoted about the axis parallel to the X-axis. The light concentration position on the luminous element 560 is shifted in the Y-axis direction. By shifting the light emitting position on the luminous element 560 in the Y-axis direction, the light distribution from from the projection lens becomes 6th emitted light shifted in the Y-axis direction.

In the sixth embodiment, a position at which the light source 2 emitted light arrives shifted in the Y-axis direction by pivoting the transmission member 4th about the axis parallel to the X axis. However, a position may be that of the light source 2 emitted light arrives to be shifted in the X-axis direction by the transmission element 4th is pivoted about an axis parallel to the Y-axis.

The condenser lens 3 can be a collimator lens by the light source 2 aligns emitted light in parallel. The diameter of a light beam on the luminous element 560 is larger in this case than the diameter of a light beam in the case of the condenser lens 3 . Thus, the parallelism of the projection lens decreases 6th emitted light. a central luminous intensity of the light distribution pattern decreases. In the case of high beam which requires a high central luminous intensity, it is not preferable that the condenser lens 3 is a collimator lens. However, in the case of a light distribution pattern illuminating a wide area, a collimator lens is effective in place of the condenser lens 3 to use.

Furthermore, it is possible to form a single light distribution pattern by using a headlamp device that has the condenser lens 3 and a headlight device using a collimator lens. In this case, the headlamp device using the collimator lens forms the shape of the entire light distribution pattern. The headlamp device that has the condenser lens 3 is used, forms a high illuminance area in the entire light distribution pattern.

Furthermore, the condenser lens 3 consist of two lenses: a collimator lens and a condenser lens. This enables the distance from the light source 2 to the condenser lens 3 free to adjust. For example, a mirror that folds a beam of light can be placed between the collimator lens and the condenser lens 3 be arranged. This allows the size of the headlight device 1 is reduced in the projection direction (Z-axis direction). "Folding a ray of light" refers to changing a direction of the ray of light by reflection.

When the transmission element 4th between the condenser lens 3 and the projection lens 6th is located, the aforementioned effects are obtained. However, it is not preferred that the transmission element 4th between the luminous element 560 and the projection lens 6th to arrange. This results from the fact that light (fluorescence) generated by exciting the luminous element 560 is typically emitted from the luminous element 560 in a scattered manner. That is, light emitted from the luminous element 560 is scattered light. Thus, the scattering of light is great. When the distance between the luminous element 560 and the projection lens 6th increases, the amount of light generated by the excitation and the projection lens increases 6th achieved, ab, and the light utilization efficiency of the headlamp device 1 decreases. In a case where the light using efficiency is within an allowable range or the like, the transmission element may 4th between the luminous element 560 and the projection lens 6th be arranged.

It is preferable that the light concentration position of the condenser lens 3 located on the luminous element 560. It is preferable that a focal position of the projection lens 6th is arranged on the luminous element 560. “On the light-emitting element 560” refers to a surface of the light-emitting element 560. As a result, the most concentrated light is converted by the light-emitting element 560 into fluorescent light, which is emitted. It is possible to see the parallelism of the projection lens 6th to increase emitted light. When performance degradation or the like may occur due to a rise in temperature of the luminous element 560 or the like, the light concentration position of the condenser lens may decrease 3 be shifted away from the surface of the luminous element 560.

In the sixth embodiment, the headlight device has been described as an example. However, the configuration of the sixth embodiment can be used as a lighting device. For example, the configuration of the sixth embodiment can be used in a lighting device that emits light according to the movement of an object. Furthermore, the configuration of the sixth embodiment temporarily changes the projection position of the illumination light, thereby improving a lighting transmission effect. A lighting device using the configuration of the sixth embodiment can provide lighting with a higher handing effect.

In the above embodiments, headlamp devices capable of changing the color temperature of light have been described. These headlight devices can be used as lighting devices. By temporarily changing the color of the projected illumination light, a lighting transmission effect is improved. A lighting device using the configuration of any of the above embodiments capable of changing the color temperature of light can provide lighting with a higher rendering effect.

Seventh embodiment

22nd Fig. 13 is a configuration diagram schematically illustrating the main components of a headlamp device 107 according to a seventh embodiment of the present invention.

As in 22nd As illustrated, the headlamp device 107 includes a light source 27, a condenser lens 37, a transmission element 4th and a projection lens 6th .

Elements that are the same as those in the first embodiment are given the same reference numerals and the description thereof is omitted. The projection lens 6th is the same as that in the first embodiment.

The transmission element 4th is the same as the transmission element described in the fourth or sixth embodiment 4th . Thus, description that overlaps the description of the fourth or sixth embodiment is omitted from the seventh embodiment by substituting the description of the fourth or sixth embodiment.

For the configurations, functions, operations, or the like of elements that are the same as those of any one of the first to sixth embodiments, even if their descriptions are omitted in the seventh embodiment, the descriptions in the first to sixth embodiments are employed. Descriptions regarding the first to sixth embodiments described in the seventh embodiment will be used as descriptions of the first to sixth embodiments. Here “mode of operation” includes the behavior of light.

The light source 27 emitted white light. The light source 27 is a light emitting diode that emits white light. For example, the light source 28 contains a blue light-emitting diode and a yellow phosphor.

In this case, the light source 27 excites the yellow phosphor using the blue light emitting diode. Alternatively, the light source 27 includes an ultraviolet light emitting diode and a white phosphor. In this case, the light source 27 excites the white phosphor using the ultraviolet light emitting diode.

Unlike the sixth embodiment, the light source 27 is not an excitation light source. The headlight device 107 does not contain a lighting element. The headlamp device 107 does not include a fluorescence generation area.

The condenser lens 37 may be the same as that in the sixth embodiment. However, the light source 27 has an angle of divergence larger than that of the light source 2 is. Thus, if the light source 27 is the same size as the light source 2 and the light receiving efficiency is improved, the condenser lens 27 is larger than the condenser lens 3 . For this reason, the condenser lens 37 is different from the condenser lens 3 according to the sixth embodiment.

The condenser lens 37 concentrates light emitted from the light source 27 at a light concentration point F7. The light concentration point F7 is located between the transmission element 4th and the projection lens 6th . In 22nd the light concentration point F7 is on the optical axis Cp of the projection lens 6th .

The condenser lens 37 can be configured using two lenses. This enables the distance between the light source 27 and the condenser lens 37 to be changed. For example, it is possible by arranging a mirror that directs a light beam between a collimator lens and a condenser lens folds the headlamp device 107 in a direction (the Z-axis direction) of the optical axis of the projection lens 6th to zoom out.

The condenser lens 37 can be configured using a single hybrid lens. The hybrid lens here is, for example, a lens with a light transmission property and a total reflection property. The condenser lens 37 may be an optical element using refraction and total reflection. For example, this optical element can concentrate light with a small angle of divergence by refraction and concentrate light with a large angle of divergence by total reflection.

In the 11th The illustrated headlight device 107 pivots the transmission element 4th about the axis S2 as in the sixth embodiment. With this, the headlamp device 107 shifts the light concentration point F7 of light emitted from the light source 27 in the Y-axis direction. The Y-axis direction is a direction perpendicular to a plane including the optical axis Cp and the axis S2.

The effects of the seventh embodiment will be described.

16 is used as a light ray tracing diagram for explaining the effects of the seventh embodiment. The explanation is based on the assumption that in 16 the light concentration point F7 to the positions of the respective areas 5a , 5b and 5c on the light element 5 is shifted. As described above, in the seventh embodiment, the luminous element 5 not used.

The light concentration point F7 is a point where light emitted from the light source 27 is concentrated on the optical axis Cp. Thus, when the light concentration point F7 becomes the position of each of the areas 5a , 5b and 5c is shifted, light emitted from the light source 27 from the position of each of the areas 5a , 5b and 5c emitted.

From the position of the light beam 5a emitted light rays 1400a propagates parallel to the optical axis Cp after passing through the projection lens 6th have passed through. From the position of the area 5b emitted light rays 1400b propagate in the -Y-axis direction obliquely to the optical axis Cp after passing through the projection lens 6th have passed through. From the position of the area 5c emitted light rays 1400c propagate in the + Y-axis direction obliquely to the optical axis Cp after passing through the projection lens 6th have passed through.

The direction in which light rays emitted from the light concentration point F7 travel varies depending on the position of the light concentration point F7. Thus, by shifting the position of the light concentration point F7 in the Y-axis direction, it is possible to shift the position irradiated by light emitted from the light source 27.

For example, when a driver is cornering, the headlight device 107 can be from the light source 2 project emitted light in the direction of travel of the vehicle. The direction of travel of the vehicle is a direction in which the vehicle turns. This makes it possible to improve the driver's visibility with respect to the direction of travel of the vehicle.

The headlamp device 107 can shift the position irradiated by light with a simple configuration. The headlamp device 107 can control the light distribution.

In the seventh embodiment, a position where light emitted from the light source 27 arrives is shifted in the Y-axis direction by the transmission member 4th is pivoted about the axis parallel to the X-axis. However, the position at which light emitted from the light source 27 arrives can be shifted in the X-axis direction by the transmission member 4th is pivoted about an axis parallel to the Y-axis.

The headlamp device 107 according to the seventh embodiment causes light emitted from the condenser lens 37 to be the transmission element 4th achieved. The headlight device 107 pivots the transmission element 4th about the axis parallel to the X axis. Here, the X-axis is an axis perpendicular to the optical axis Cp of the projection lens 6th . The headlamp device 107 shifts the light concentration point F7 in the Y-axis direction. Here, the Y-axis is an axis perpendicular to both the optical axis Cp and the X-axis. The headlamp device 107 shifts the light distribution from the projection lens 6th emitted light in the Y-axis direction by shifting the light concentration point F7 in the Y-axis direction to shift the irradiation position (emission direction) of the light in the Y-axis direction.

When the light source 27 has a large divergence angle like a light emitting diode, it is not preferable that the condenser lens 37 be a collimator lens. The collimator lens converts from the light emitted from the light source 27 into parallel light. This is because when a light emitting diode is used as the light source 27, the diameter of a light beam reaching the condenser lens 37 increases so that the parallelism of from the projection lens 6th emitted light decreases. When the decrease in parallelism of the light is within an allowable range, the collimator lens can be used even if the light source 27 is a light emitting diode.

The transmission element 4th can be anywhere between the condenser lens 37 and the projection lens 6th condition. The position of the transmission element 4th is not optically restricted. In contrast to the sixth exemplary embodiment, light is not scattered by the luminous element 560. The light scattering of light rays passing through the light concentration point F7 is smaller than that of scattered light.

Compared with the first embodiment, the increase in the distance between the light concentration point F7 and the projection lens deteriorates 6th the light utilization efficiency not. Thus, it is possible to determine the distance from the light concentration point F7 to the projection lens 6th compared to the case where the luminous element 560 is arranged. When the parallelism of from the projection lens 6th emitted light beams is enlarged, it is preferable that the distance between the light concentration point F7 and the projection lens 6th is great.

23A , 23B and 23C are diagrams illustrating results of light ray tracing when the transmission element 4th between the light concentration point F7 and the projection lens 6th is arranged.

the 23A , 23B and 23C are explanatory diagrams illustrating simulation results of light ray tracing in the seventh embodiment.

The transmission element 4th in 23A is perpendicular to the optical axis C. .

The transmission element 4th in 23B is relative to the state in 23A Pivoted counterclockwise when viewed from the -X axis direction side.

The transmission element 4th in 23C is relative to the state of 23A Pivoted clockwise when viewed from the -X axis direction side.

The pivot angle of the transmission element 4th in the 23B and 23C are, for example, 30 degrees each.

In the 23A , 23B and 23C are the light paths after passing through the projection lens 6th different from each other. The light rays 700a in 23A propagate parallel to the optical axis Cp. The light rays 700b in 23B propagate in the Y-axis direction obliquely to the optical axis Cp. The light rays 700c in 23C propagate in the + Y-axis direction obliquely to the optical axis Cp.

the 23A , 23B and 23C illustrate the light beams 700a, 700b and 700c emitted from a center of the light source 27. The following is a position of the light source 27 on the optical axis C. emitted light described.

Light emitted from the light source 27 plants in the + Z-axis direction with an emission angle whose center is on the optical axis C. lies away.

The light traveling in the + Z-axis direction is incident on the condenser lens 37.

The light incident on the condenser lens 37 is on the optical axis C. concentrated.

An impact surface 41 of the transmission element 4th in 23A is perpendicular to the optical axis C. . From the light rays 700a, the light ray is planted on the optical axis C. without being broken at the impact surface 41. Thus, the light rays 700a plant themselves in parallel with the optical axis C. continued after going through the projection lens 6th have passed through. A focal point of the projection lens 6th coincides with the light concentration point F7.

The impact surface 41 of the transmission element 4th in 23B is, for example, when viewed from the -X axis direction side with respect to the optical axis C. swiveled 30 degrees counterclockwise. Of the light beams 700b, the light beam becomes on the optical axis C. is broken at the landing surface 41 in the + Y-axis direction and propagates. Thus, there is a center (the optical Cp) of the projection lens 6th on the -Y axis direction side of the light beam on the optical axis C. . Thus, the plant from the projection lens 6th emitted light beams 700b proceed in the Y-axis direction with respect to the optical axis Cp.

The impact surface 41 of the transmission element 4th in 23C is around 30 when viewed from the -X-axis direction side, for example Degree with respect to the optical axis C. pivoted clockwise. Of the light beams 700c, the light beam becomes on the optical axis C. is broken at the landing surface 41 in the -Y axis direction and propagates. Thus, the center (the optical axis Cp) of the projection lens is located 6th on the + Y-axis direction side of the light beam on the optical axis C. . Thus, the plant from the projection lens 6th emitted light beams 700c proceed in the + Y-axis direction with respect to the optical axis Cp.

When the transmission element 4th is located between the condenser lens 37 and the light concentration point F7, the headlamp device 107 operates in the same manner.

With the above-described operation, when the landing surface 41 of the transmission member 4th perpendicular to the optical axis C. is, the light rays 700a emitted from the light source 27 from the projection lens 6th than emits light parallel to the optical axis Cp.

When the impact surface 41 of the transmission element 4th when viewed from the -Y axis direction side with respect to the optical axis C. is pivoted counterclockwise, the light beams 700b emitted from the light source 27 are released from the projection lens 6th than light inclined in the -Y axis direction with respect to the optical axis Cp.

When the impact surface 41 of the transmission element 4th when viewed from the -X axis direction side with respect to the optical axis C. is pivoted clockwise, the light beams 700c emitted from the light source 27 are released from the projection lens 6th than light inclined in the + Y-axis direction with respect to the optical axis Cp.

The angle of the projection lens 6th emitted light with respect to the optical axis Cp depends on the thickness or the refractive index of the transmission element 4th away. To facilitate the explanation, the transmission element 4th described as a parallel plate.

In the above description, the light beams 700a, 700b and 700c are concentrated at the light concentration point F7. Then, the light beams 700a, 700b and 700c pass through the projection lens 6th directed in parallel light.

However, the position of the light concentration point F7 at which the light beams 700a, 700b, and 700c are concentrated can be moved. It is not imperative that a focal position of the projection lens 6th coincides with the light concentration point F7. It is possible to adjust the distance between the light concentration point F7 and the projection lens 6th decrease, thereby causing the projection lens 6th emits diverging light.

<Fourth modification>

24 Fig. 13 is a configuration diagram schematically illustrating the main components of a fourth modification. A transmission element 4th and a projection lens 6th are the same as those in the seventh embodiment.

As in 24 As illustrated, a headlamp device 108 includes light sources 2r, 2g and 2b, collimator lenses 20r, 20g and 20b, the transmission element 4th and the projection lens 6th . The headlamp device 108 may include a condenser lens 38 or a diffusion element 58.

The light sources 2r, 2g and 2b are, for example, light sources that emit light with different wavelengths. For example, the light source 2r emits light in a red wavelength band. The light source 2g emits light in a green wavelength band. The light source 2b emits light in a blue wavelength band.

For example, the blue wavelength band comprises 430 nm to 485 nm. The green wavelength band comprises 500 nm to 570 nm. The red wavelength band comprises 600 nm to 650 nm.

The light sources 2r, 2g and 2b are arranged in the Y-axis direction. The light sources 2r, 2g and 2b are arranged, for example, at regular intervals. In the fourth modification are the light sources 2 arranged in three rows and one column. In 24 they are arranged in three rows in the Y-axis direction and in one column in the Y-direction. However, the light sources 3 be arranged in a matrix of three rows and three columns, for example three rows in the Y-axis direction and three columns in the X-axis direction.

An optical axis Cs of the light source 2g coincides with an optical axis C. of the condenser lens 38. The light source 2r is located on the + Y-axis direction side of the light source 2g. The light source 2b is located on the -Y axis direction side of the light source 2g. Optical axes Cs of the light sources 2r and 2b are parallel to the optical axis Cs of the light source 2g.

In the fourth modification, the light sources 2r, 2g and 2b are described as laser light sources. The light sources 2r, 2g and 2b can be light emitting diodes.

Light emitted from the light sources 2r, 2g and 2b is collimated by the collimator lenses 20r, 20g and 20b. The collimator lenses 20r, 20g and 20b emit light parallel to the optical axes Cs. The optical axes Cs are optical axes of the light sources 2r, 2g and 2b.

The collimator lens 20r is located on the + Z-axis direction side of the light source 2r. The collimator lens 20g is located on the + Z-axis direction side of the light source 2g. The collimator lens 20b is located on the + Z-axis direction side of the light source 2b.

An optical axis Ca of the collimator lens 20r coincides with the optical axis Cs of the light source 2r. An optical axis Ca of the collimator lens 20g coincides with the optical axis Cs of the light source 2g. An optical axis Ca of the collimator lens 20b coincides with the optical axis Cs of the light source 2b.

In the fourth modification, the diffusion member 58 is located at a position where light is concentrated by the condenser lens 38. However, as described in the above seventh embodiment, the diffusion member 58 can be omitted. In the fourth modification, effects in the case of using the diffusion member 58 will be described together with effects in the case of using the plurality of light sources 2r, 2g, and 2b.

Light emitted from the collimator lenses 20r, 20g, and 20b is concentrated at the position of the diffusion member 58 by the condenser lens 38. Light emitted from the collimator lenses 20r, 20g and 20b reaches the diffusion element 58 after passing through the transmission element 4th has passed through. As in the seventh embodiment, the transmission element 4th between the diffusion member 58 (light concentration position) and the projection lens 6th being.

Light emitted from the collimator lenses 20r, 20g and 20b is incident on the condenser lens 38 as parallel light. Thus, light emitted from the collimator lenses 20r, 20g and 20b is concentrated at a single light concentration point.

The transmission element 4th pivots about an axis S2 parallel to the X-axis. The transmission element 4th shifts the light concentration position of light emitted from the light sources 2r, 2g, and 2b in the Y-axis direction. However, it is also possible for the transmission element 4th about an axis parallel to the Y-axis, thereby shifting the position where light emitted from the light sources 2r, 2g and 2b arrives in the X-axis direction.

In the fourth modification, light emitted from the condenser lens 38 reaches the transmission element 4th . The transmission element 4th is pivoted about the axis S2 parallel to the X-axis. The transmission element 4th shifts the light concentration position on the diffusion member 58 in the Y-axis direction. Due to the shift in the light concentration position, a light emitting position on the diffusion element 58 is shifted. By shifting the light emitting position on the diffusion element 58, the headlight device 108 shifts the light distribution from the projection lens 6th emitted light. In the fourth modification, the headlamp device 108 shifts the light distribution from the projection lens by shifting the light emitting position on the diffusion member 58 in the Y-axis direction 6th emitted light in the Y-axis direction.

When the light sources 2r, 2g and 2b are laser light sources, the divergence angles of the light sources 2r, 2g and 2b are small. Thus, the condenser lens 38 can be omitted. Without using the condenser lens 38, the collimator lenses 20r and 20b are not on the optical axis C. are located to the optical axis C. made eccentric. That is, the collimator lens 20r is eccentric in the Y-axis direction. The optical axis Ca of the collimator lens 20r is shifted in the -Y axis direction. The collimator lens 20b is eccentric in the + Y-axis direction. The optical axis Ca of the collimator lens 20b is shifted in the + Y-axis direction. This can cause light from the light sources 2r, 2g and 2b to reach the diffusion element.

However, the use of the condenser lens 38 enables a distance in the Z-axis direction to be shortened. That is, the distance from the collimator lenses 20r, 20g, and 20b to the diffusion member 58 in the Z-axis direction can be shortened. This enables the headlight device 108 to be downsized.

In the fourth modification, the light sources 2r, 2g and 2b are arranged in the Y-axis direction. However, the light sources 2r, 2g and 2b can be arranged in any manner. For example, the light sources 2r, 2g and 2b can be at the vertices of an equilateral triangle, the center of which is on the optical axis C. lies in a plane perpendicular to the optical axis C. condition.

For example, even if the diffusion member 58 is not disposed in the headlamp device 108, the effect of shifting from the projection lens may be 6th emitted light in the Y-axis direction can be obtained. However, if there are three monochromatic light beams are combined, a color unevenness in that of the projection lens 6th emitted light occur.

By placing the diffusion element 58 between the transmission element 4th and the projection lens 6th becomes a color unevenness in that of the projection lens 6th emitted light reduced. The diffusion element 58 can be between the light sources 2r, 2g and 2b and the projection lens 6th be arranged. However, it is preferred that the diffusion element 58 be between the transmission element 4th and the projection lens 6th is arranged. This follows from the fact that the size of the light beam becomes a minimum.

the 25A , 25B and 25C are diagrams illustrating an example of light ray tracing results representing the operation of the fourth modification.

The transmission element 4th in 25A is perpendicular to the optical axis C. .

The transmission element 4th in 25B is relative to the state of FIG 25A pivoted counterclockwise.

The transmission element 4th in 25C is relative to the state of FIG 25A pivoted clockwise.

The pivot angle of the transmission element 4th in the 25B and 25C are each, for example, 30 degrees.

Light paths after passing through the transmission element 4th in the 25A , 25B and 25C are mutually different.

The light rays 800ar, 800ag and 800ab in 25A are broken at the impact surface 41 and reproduce. The light rays 800ar, 800ag and 800ab are at the position of the optical axis C. concentrated on the diffusion element 58.

The light beams 800br, 800bg and 800bb in 25B are broken at the landing surface 41 in the + Y-axis direction and propagate. The light beams 800br, 800bg and 800bb are at one of the position of the optical axis C. in the + Y-axis direction shifted position concentrated on the diffusion member 58.

The light beams 800cr, 800cg and 800cb in 25C are broken at the impact surface 5'41 in the -Y-axis direction and propagate. The light beams 800cr, 800cg and 800cb are at one of the position of the optical axis C. in the -Y-axis direction shifted position concentrated on the diffusion member 58.

the 25A , 25B and 25C illustrate the light rays 800ar, 800ag, 800ab, 800br, 800bg, 800bb, 800cr, 800cg and 800cb emitted from the centers of the light sources 2r, 2g and 2b.

The light beams 800ar, 800br and 800cr are light beams emitted from the light source 2r. The light beams 800ag, 800bg and 800cg are light beams emitted from the light source 2g. The light beams 800ab, 800bb and 800cb are light beams emitted from the light source 2b.

Light emitted from the light sources 2r, 2g and 2b propagates in the + Z-axis direction with the emission angles centered on the optical axes Cs of the respective light sources 2r, 2g and 2b.

The propagation of light in the + Z-axis direction is collimated by the collimator lenses 20r, 20g and 20b. The parallel light (parallel light) propagates in the + Z-axis direction.

The light propagating in the + Z-axis direction (parallel light) is incident on the condenser lens 38.

The light (parallel light) incident on the condenser lens 38 is concentrated on the diffusion element 58.

In the case of 25A is the impact surface 41 of the transmission element 4th perpendicular to the optical axis C. . The light beams 800ar, 800ag and 800ab are refracted at the impingement surface 41. Then the light rays 800ar, 800ag and 800ab are propagated so that they are on the optical axis C. can be concentrated at the position of the diffusion member 58. Thus, the light concentration position of the light beams 800ar, 800ag and 800ab is on the optical axis C. . In 25A the light beams 800ar, 800ag and 800ab become at the position of the optical axis C. concentrated on the diffusion element 58.

In the case of 25B is the impact surface 41 of the transmission element 4th viewed from the -X axis direction side with respect to the optical axis C. swiveled 30 degrees counterclockwise. Thus, the light concentration position of the light beams is 800br, 800bg, and 800bb with respect to the optical axis C. shifted in the + Y-axis direction. In 25B the light beams 800br, 800bg and 800bb are at a position on the diffusion element 58 on the + Y- Axis direction side from the optical axis C. concentrated.

In the case of 25C is the impact surface 41 of the transmission element 4th when viewed from the -X axis direction side with respect to the optical axis C. swiveled 30 degrees clockwise. Thus, the light concentration position of the light beams is 800cr, 800cg, and 800cb with respect to the optical axis C. shifted in the -Y axis direction. In 25C the light beams 800cr, 800cg and 800cb become at a position on the diffusion member 58 on the -Y-axis direction side of the optical axis C. concentrated.

By the above-described operation, when the landing surface 41 of the transmission member 4th perpendicular to the optical axis C. is, the light beams 800ar, 800ag and 800ab emitted from the light sources 2r, 2g and 2b at the position of the optical axis C. concentrated on the diffusion element 58.

When the impact surface 41 of the transmission element 4th when viewed from the -X axis direction side with respect to the optical axis C. is pivoted counterclockwise, the light beams 800br, 800bg and 800bb emitted from the light sources 2r, 2g and 2b become at a position on the diffusion member 58 on the + Y-axis direction side from the optical axis C. concentrated.

When the impact surface 41 of the transmission element 4th when viewed from the -X axis direction side with respect to the optical axis C. is pivoted clockwise, the light beams 800cr, 800cg and 800cb emitted from the light sources 2r, 2g and 2b become at a position on the diffusion member 68 on the -Y-axis direction side from the optical axis C. concentrated.

By pivoting the transmission element 4th it is possible to shift the light concentration position on the diffusion member 58 of excitation light emitted from the condenser lens 38.

The light concentration position on diffusion element 58 depends on the thickness or index of refraction of the transmission element 4th away. Thus, the pivot angle of the transmission element 4th changed. To facilitate the explanation, the transmission element 4th described as a parallel plate.

In the present description, the light beams 800ar, 800ag, 800ab, 800br, 800bg, 800bb, 800cr, 800cg and 800cb are concentrated on the diffusion element 58. However, the light concentration position of the light beams 800ar, 800ag, 800ab, 800br, 800bg, 800bb, 800cr, 800cg, and 800cb need not necessarily be on the diffusion member 58. The light concentration position of the light beams 800ar, 800ag, 800ab, 800br, 800bg, 800bb, 800cr, 800cg, and 800cb can be in a direction of the optical axis C. be shifted with respect to the diffusion element 58.

16 is used as a light ray tracing diagram for explaining effects of the fourth modification. The explanation is made by replacing the luminous element 5 through diffusion element 58 in 16 .

The diffusion element 58 is located on the optical axis C. . The diffusion member 58 is located at a position where light emitted from the light sources 2r, 2g, and 2b is concentrated. Thus, on the area 5a , 5b or 5c concentrated light obtained by combining light emitted from the light sources 2r, 2g and 2b. Thus, light emitted from the diffusion member 58 is obtained by combining lights emitted from the light sources 2r, 2g, and 2b.

The ones from the area 5a emitted light rays 1400a correspond to light obtained by combining the light rays 800ar, 800ag and 800ab in 15A was obtained. Light obtained by combining the light beams 800ar, 800ag and 800ab travels in parallel with the optical axis Cp.

The ones from the area 5b emitted light beams 1400b correspond to light obtained by combining the light beams 800br, 800bg, and 800bb in 25B received. Light obtained by combining the light beams 800br, 800bg and 800bb is planted in the -Y axis direction obliquely to the optical axis Cp after passing through the projection lens 6th away.

The ones from the area 5c emitted light beams 1400c correspond to light obtained by combining the light beams 800cr, 800cg and 800cb in 25C was obtained. Light obtained by combining the light beams 800cr, 800cg and 800cb plants in the + Y-axis direction obliquely to the optical Cp after passing through the projection lens 6th away.

Thus, by changing the position on the diffusion member 58 of light beams emitted from the diffusion member 58, it is possible to change the direction in which the light beams travel. By shifting light emitted from the light sources 2r, 2g and 2b on the diffusion member 58, it is possible to determine the irradiation position of light from the projection lens 6th to move.

For example, when a driver is turning a corner, the headlight device 108 can project light emitted from the light sources 2r, 2g and 2b in the direction of travel of the vehicle. The direction of travel of the vehicle is a direction in which the vehicle turns. This makes it possible to improve the driver's visibility of the direction of travel of the vehicle.

The headlamp device 108 can shift the position irradiated by the light with a simple configuration. The headlight device 108 can control the light distribution.

As described above, in the fourth modification, an AFS or ADB is obtained by arranging the components in the order of the light sources 2r, 2g and 2b, collimator lenses 20r, 20g and 20b, condenser lens 38, the transmission member 4th and the diffusion element 58.

Furthermore, by changing an output value (amount of light) of each of the light sources 2r, 2g and 2b, it is possible to determine the color temperature of the projection lens 6th to change emitted white light. Therefore, in addition to changing the light distribution, the color temperature can be changed.

<Fifth modification>

26A , 26B and 26C are explanatory diagrams illustrating simulation results of light ray tracing of a headlamp device 100 according to a fifth modification. In the 26A , 25B and 25C is the projection lens 6th omitted.

In 26A is a reflecting surface 491 of a reflecting member 49 at 45 degrees with respect to the optical axis C. inclined when viewed from the -X axis direction side. Thus, light reaching them from the -Y-axis direction side is reflected in the + Z-axis direction. This state is taken as a reference position of the reflecting surface 491.

In 26B For example, when viewed from the -X-axis direction side, the reflecting surface 491 of the reflecting member 49 is pivoted counterclockwise with respect to the reference position of the reflecting surface 491. In 26B is the reflecting surface 491 of the reflecting member 49 by 47 degrees with respect to the optical axis C. inclined when viewed from the -X axis direction side.

In 26C For example, when viewed from the -X axis direction side, the reflecting surface 491 of the reflecting member 49 is pivoted clockwise with respect to the reference position of the reflecting surface 491. In 26C is the reflecting surface 491 of the reflecting member 49 by 43 degrees with respect to the optical axis C. inclined when viewed from the -X axis direction side.

the 26A , 26B and 26C illustrate a configuration obtained by replacing the transmission member in FIG 15th is obtained by the reflective element 49. The elements other than the reflective element 49 are the same as those of the headlamp device 105, and hence they are given the same reference numerals.

As in 22nd As illustrated, the headlamp device 107 includes the light source 27, the condenser lens 37, the transmission element 4th and the projection lens 6th .

In the fifth modification, light emitted from the light source 27 travels with an emission angle centered on the optical axis Cs. The light source 27 emits light in the + Y-axis direction.

The light traveling in the + Y-axis direction is converted into the concentrated light by the condenser lens 37. The concentrated light propagates in the + Y-axis direction.

The light propagating in the + Y-axis direction (concentrated light) reaches the reflecting surface 491 of the reflecting member 49. The light reaching the reflecting surface 491 is reflected by the reflecting surface 491. The light reflected by the reflection surface 491 propagates in the + Z-axis direction.

The light propagating in the + Z-axis direction is concentrated.

The concentrated light comes through the projection lens 6th (not illustrated) directed parallel. The parallel light (parallel light) propagates in the + Z-axis direction.

As in 26A As illustrated, light emitted from the light source 27 in the + Y-axis direction is concentrated by the condenser lens 37. The light concentrated by the condenser lens 37 is concentrated on the optical axis Cp.

Light 900 a emitted from the condenser lens 37 is reflected by the reflective surface 491 of the reflective element 49. The traveling direction of a central light beam of the light 900a reflected by the reflection surface 491 is changed by 90 degrees by the reflection surface 491. The light 900a reflected by the reflection surface 491 is incident on the optical axis Cp of the projection lens 6th concentrated.

In 26A becomes the optical axis C. of the condenser lens 37 bent by 90 degrees by the reflective element 49. The following description assumes that even when the reflective member 49 is pivoted about the rotation axis, the optical axis C. of the condenser lens 37 from the reflective element 49 to the projection lens 6th the optical axis is in the state in which the optical axis C. is bent by 90 degrees by the reflective member 49 (the state of 26A) . That is, the description is made on the assumption that the optical axis C. of the condenser lens 37 in the state of 26A remains even if the reflection member 49 is pivoted. In the 26A , 26B and 26C the optical axis is correct C. on the side of the projection lens 6th from the reflection member 49 coincides with the optical axis Cp. The axis of rotation of the reflection element 49 is, for example, a third axis perpendicular to the optical axis of the projection lens.

As in 26B As illustrated, when viewed from the -X-axis direction side, the reflective member 49 is pivoted counterclockwise from the reference position of the reflective surface 491. In this case, light concentrated by the condenser lens 37 is concentrated on the + Y-axis side from the optical axis Cp. That is, the light concentration position of light concentrated by the condenser lens 37 is shifted from the optical axis Cp in the + Y-axis direction.

In 26B is an angle between the optical axis C. bent by 90 degrees by the reflective element 49, and the reflective element 49 (reflective surface 491) greater than 45 degrees. The reflective element 49 (reflective surface 491) in 26B is for example 47 degrees with respect to the optical axis C. inclined. Thus, the reflective element 49 (reflective surface 491) in 26B inclined by 47 degrees with respect to the optical axis Cp.

Thus, a central light beam of a bundle of light beams 900b reflected by the reflection member 49 travels in the + Z-axis direction while traveling by 4 degrees in the + Y-axis direction with respect to the optical axis C. is inclined. The light beams 900b reflected by the reflection member 49 are concentrated on the + Y-axis direction side from the light concentration position in the case where the reflection surface 491 is at the reference position.

As in 26C As illustrated, when viewed from the -X-axis direction side, the reflective element 49 is pivoted clockwise from the reference position of the reflective surface 491. In this case, light concentrated by the condenser lens 37 is concentrated on the -Y axis side from the optical axis Cp. That is, the light concentration position of light concentrated by the condenser lens 37 is shifted from the optical axis Cp in the -Y axis direction.

In 26C is an angle between the optical axis C. bent by 90 degrees by the reflective element 49 and the reflective element 49 (reflective surface 491) smaller than 45 degrees. The reflective element 49 (reflective surface 491) in 26C is for example 43 degrees with respect to the optical axis C. inclined. Thus, the reflective element 49 (reflective surface 491) in 26C inclined 43 degrees with respect to the optical axis Cp.

Thus, a central light beam of a bundle of light beams 900c reflected by the reflection member 49 travels in a + Z-axis direction while traveling by 4 degrees in the -Y-axis direction with respect to the optical axis C. is inclined. The light rays 900c reflected by the reflection member 49 are concentrated on the -Y axis direction side from the light concentration position in the case where the reflection surface 491 is at the reference position.

When the reflective member 49 is used in this way, the headlamp device increases in size in the Y-axis direction. However, the headlamp device decreases in size in the Z-axis direction.

When the transmission element 4th is used, the components are arranged in the Z-axis direction (optical axis direction Cp). When the reflective member 49 is used, it is possible to arrange components off the optical axis Cp.

When the configuration of FIG: 26 matches the configuration of 15th is compared, the amount of displacement of the light with respect to the pivot angle of the transmission element 4th smaller than the amount of shift of light with respect to the pivot angle of the reflection member 49. When the reflection member 49 is used, the amount of shift of light with respect to the pivot angle. Thus, for example, when it is used for a headlamp intended to have a projection distance of 25 m, the accuracy of setting the reflective element 49 becomes greater than the accuracy of setting the transmission element 4th .

The projection lens 6th is in the 26A , 26B and 26C not illustrated. The projection lens 6th is on the + Z axis side of the light concentration position F7. However, is for example, the distance between the light concentration position F7 and the projection lens 6th 5 mm. In this case, the distance of shifting the light at a position 25 m in front of the headlamp device is 5000 times the distance of shifting the light in a plane (light concentration plane (Pf) including the light concentration position F7 and perpendicular to the optical axis Cp. This is determined by calculating 25m / 5mm = 5000. Thus, if the light is from the light source 2 is shifted by one mm in the light concentration plane Pf, the position 25 m in front of the headlight device at which the light arrives, shifted by 5 m.

Thus, if the transmission element 4th is used, fine control of the light distribution is easier. Furthermore, it is by changing the thickness or the refractive index of the transmission element 4th possible to change the amount of displacement with respect to the pivot angle.

Further, if the reflectance (97%) of the reflective element 49 and the transmittance (99%) of the transmission element 4th be compared, the permeability of the transmission element 4th generally higher. Thus, when considering the light utilization efficiency, it is preferable to the transmission element 4th to use.

<Attachments>

Appendices are described below on the basis of the above exemplary embodiments.

<Appendix 1>

• eine Lichtquelle, die Anregungslicht emittiert;
• einen Wellenlängen-Auswahlbereich, der das Anregungslicht empfängt und Licht mit verschiedenen Farbtemperaturen emittiert; und
• eine Projektionslinse, das Licht, das von dem Wellenlängen-Auswahlbereich emittiert wurde und die verschiedenen Farbtemperaturen hat, projiziert, wobei:
  • der Wellenlängen-Auswahlbereich ein kondensierendes optisches Element und einen Fluoreszenzerzeugungsbereich enthält;
  • der Fluoreszenzerzeugungsbereich Bereiche hat und Licht emittiert, wobei eine Farbtemperatur des emittierten Lichts in Abhängigkeit davon, welcher der Bereiche das Anregungslicht empfängt, variiert;
  • das kondensierende optische Element das von der Lichtquelle emittierte Anregungslicht konzentriert; und
  • das konzentrierte Anregungslicht selektiv einen Bereiche erreicht.

Headlight device, which comprises:

• a light source that emits excitation light;
• a wavelength selection section that receives the excitation light and emits light having different color temperatures; and
• a projection lens that projects light emitted from the wavelength selection area and having different color temperatures, wherein:
  • the wavelength selection area includes a condensing optical element and a fluorescence generating area;
  • the fluorescence generating region has regions and emits light, a color temperature of the emitted light varying depending on which of the regions receives the excitation light;
  • the condensing optical element concentrates the excitation light emitted from the light source; and
  • the concentrated excitation light selectively reaches an area.

<Appendix 2>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement enthält, das Fluoreszenzlicht emittiert;
• das Leuchtelement die Bereiche, die Licht mit verschiedenen Farbtemperaturen emittieren, enthält; und
• das kondensierende optische Element in einer Richtung senkrecht zu einer optischen Achse des kondensierenden optischen Elements verschoben wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating region includes a luminous element that emits fluorescent light;
• the luminous element includes the areas that emit light with different color temperatures; and
• the condensing optical element is displaced in a direction perpendicular to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 3>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement enthält, das Fluoreszenzlicht emittiert;
• das Leuchtelement die Bereiche enthält, die Licht mit verschiedenen Farbtemperaturen emittieren; und
• das kondensierende optische Element um eine Achse senkrecht zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating region includes a luminous element that emits fluorescent light;
• the luminous element contains the areas that emit light with different color temperatures; and
• the condensing optical element is pivoted about an axis perpendicular to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 4>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement, das Fluoreszenzlicht emittiert, und ein Wellenlängen-Auswahlelement, das Wellenlängen von durch das Wellenlängen-Auswahlelement hindurchgehendem Licht auswählt und Licht von Wellenlängen, die andere als die ausgewählten Wellenlängen sind, reflektiert;
• das Wellenlängen-Auswahlelement die Bereiche enthält, die Licht verschiedener Wellenlängen durchlassen; und
• das kondensierende optische Element in einer Richtung senkrecht zu einer optischen Achse des kondensierenden optischen Elements verschoben wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating portion, a luminous element that emits fluorescent light and a wavelength selection element that selects wavelengths of light passing through the wavelength selection element and reflects light of wavelengths other than the selected wavelengths;
• the wavelength selection element includes the regions that transmit light of different wavelengths; and
• the condensing optical element in a direction perpendicular to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 5>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement, das Fluoreszenzlicht emittiert, und ein Wellenlängen-Auswahlelement, das Wellenlängen von Licht, die durch das Wellenlängen-Auswahlelement hindurchgehen, auswählt und Licht von Wellenlängen, die andere als die ausgewählten Wellenlängen sind, reflektiert;
• das Wellenlängen-Auswahlelement die Bereiche enthält, die Licht von verschiedenen Wellenlängen durchlassen; und
• das kondensierende optische Element um eine Achse senkrecht zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating portion, a luminous element that emits fluorescent light and a wavelength selection element that selects wavelengths of light passing through the wavelength selection element and reflects light of wavelengths other than the selected wavelengths;
• the wavelength selection element includes the regions that transmit light of different wavelengths; and
• the condensing optical element is pivoted about an axis perpendicular to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 6>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement enthält, das Fluoreszenzlicht emittiert;
• das Leuchtelement die Bereiche enthält, die Licht mit verschiedenen Farbtemperaturen emittieren; und
• das Leuchtelement in einer Richtung senkrecht zu einer optischen Achse des kondensierenden optischen Elements verschoben wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating region includes a luminous element that emits fluorescent light;
• the luminous element contains the areas that emit light with different color temperatures; and
• the luminous element is displaced in a direction perpendicular to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 7>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement, das Fluoreszenzlicht emittiert, und ein Übertragungselement, das das konzentrierte Licht empfängt und das konzentrierte Licht zu dem Leuchtelement hin emittiert, enthält;
• das Übertragungselement um eine Achse senkrecht zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird;
• das Leuchtelement die Bereiche, die Licht mit verschiedenen Farbtemperaturen emittieren enthält; und
• das Übertragungselement um die Achse geschwenkt wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating region includes a luminous element that emits fluorescent light and a transmission element that receives the concentrated light and emits the concentrated light toward the luminous element;
• the transmission element is pivoted about an axis perpendicular to an optical axis of the condensing optical element;
• the luminous element includes the areas that emit light with different color temperatures; and
• the transmission element is pivoted about the axis, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 8>

• der Fluoreszenzerzeugungsbereich ein Wellenlängen-Auswahlelement enthält, das Wellenlängen des durch das Wellenlängen-Auswahlelement hindurchgehenden Lichts auswählt und Licht von Wellenlängen, die andere als die ausgewählten Wellenlängen sind, reflektiert; und
• das Wellenlängen-Auswahlelement sich zwischen dem Übertragungselement und dem Leuchtelement befindet.

The headlamp device according to Annex 7, in which:

• the fluorescence generating portion includes a wavelength selection element that selects wavelengths of the light passing through the wavelength selection element and reflects light of wavelengths other than the selected wavelengths; and
• the wavelength selection element is located between the transmission element and the luminous element.

<Appendix 9>

• der Fluoreszenzerzeugungsbereich ein Leuchtelement, das Fluoreszenzlicht emittiert, enthält;
• das Leuchtelement die Bereiche, die Licht mit verschiedenen Farbtemperaturen emittieren, enthält; und
• das Leuchtelement um eine Achse parallel zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird, wodurch bewirkt wird,
• dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating region includes a luminous element that emits fluorescent light;
• the luminous element includes the areas that emit light with different color temperatures; and
• the luminous element is pivoted about an axis parallel to an optical axis of the condensing optical element, whereby the effect is,
• that the concentrated light selectively reaches one of the areas.

<Appendix 10>

The headlamp device according to any one of Appendices 2, 3, 6 and 8, wherein: the fluorescence generating region includes a wavelength selection element that selects wavelengths of light passing through the wavelength selection element and light of wavelengths other than the selected wavelengths, reflected; and
the wavelength selection element is located between the condensing optical element and the luminous element.

<Appendix 11>

• der Fluoreszenzerzeugungsteil ein Leuchtelement, das Fluoreszenzlicht emittiert, und ein Wellenlängen-Auswahlelement, das Wellenlängen von durch das Wellenlängen-Auswahlelement hindurchgehendem Licht auswählt und Licht von Wellenlängen, die andere als die ausgewählten Wellenlängen sind, reflektiert;
• das Wellenlängen-Auswahlelement die Bereiche enthält, die Licht von verschiedenen Wellenlängen durchlassen; und
• das Wellenlängen-Auswahlelement um eine Achse parallel zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

The headlamp device according to Annex 1, in which:

• the fluorescence generating part, a luminous element that emits fluorescent light and a wavelength selection element that selects wavelengths of light passing through the wavelength selection element and reflects light of wavelengths other than the selected wavelengths;
• the wavelength selection element includes the regions that transmit light of different wavelengths; and
• the wavelength selection element is pivoted about an axis parallel to an optical axis of the condensing optical element, thereby causing the concentrated light to selectively reach one of the regions.

<Appendix 12>

• eine Lichtquelle, die Anregungslicht emittiert;
• ein kondensierendes optisches Element, das das Anregungslicht empfängt, das von der Lichtquelle emittierte Anregungslicht in konzentriertes Licht umwandelt, und das konzentrierte Licht emittiert;
• ein Übertragungselement, das das konzentrierte Licht empfängt, um eine Achse senkrecht zu einer optischen Achse des kondensierenden optischen Elements geschwenkt wird, und das konzentrierte Licht emittiert; und
• ein Leuchtelement, das das von dem Übertragungselement emittierte Licht empfängt und Fluoreszenzlicht emittiert, wobei:
  • das Leuchtelement Bereiche enthält, die Licht mit der gleichen Farbtemperatur emittieren, und
  • das Übertragungselement um die Achse geschwenkt wird, wodurch bewirkt wird, dass das konzentrierte Licht selektiv einen der Bereiche erreicht.

Headlight device, which comprises:

• a light source that emits excitation light;
• a condensing optical element that receives the excitation light, converts the excitation light emitted from the light source into concentrated light, and emits the concentrated light;
• a transmission element that receives the concentrated light, is pivoted about an axis perpendicular to an optical axis of the condensing optical element, and emits the concentrated light; and
• a luminous element that receives the light emitted by the transmission element and emits fluorescent light, wherein:
  • the luminous element contains areas which emit light with the same color temperature, and
  • the transmission element is pivoted about the axis, thereby causing the concentrated light to selectively reach one of the regions.

The exemplary embodiments described above use terms such as “parallel” or “perpendicular”, which indicate the positional relationships between parts or the shapes of parts. These terms contain areas that take into account manufacturing tolerances, assembly variations, or the like. Thus, when the claims contain descriptions indicating the positional relationships between parts or the shapes of parts, those descriptions include ranges that allow for manufacturing tolerances, assembly variations, or the like.

Furthermore, although the embodiments of the present invention are as described above, the present invention is not limited by these embodiments.

List of reference symbols

1

Headlight device

2

Light source

3

Condenser lens

4th

Transmission element

5

Luminous element

5a

Area of luminous element 5

5b

Area of luminous element 5

5c

Area of luminous element 5

6th

Projection lens

C.

Optical axis

Claims (4)

A lighting device (103, 108) comprising: a light source (2, 27, 2r, 2g, 2b) that emits light; a condensing optical element (3, 37, 38) which converts the light emitted from the light source (2, 27, 2r, 2g, 2b) into concentrated light and emits the concentrated light; a luminous element (53a) which receives, as excitation light, the light emitted from the condensing optical element (3, 37, 38) and emits a single type of fluorescent light; a projection lens (6) that projects the fluorescent light emitted from the luminous element (53a); a wavelength selection element (7) that selects wavelengths of light passing through the wavelength selection element and reflects light of wavelengths other than the selected wavelengths, the wavelength selection element (7) sandwiching between the condensing optical element (3 , 37, 38) and the luminous element (53a), and which transmits the concentrated light to the luminous element (53a) and reflects part of the fluorescent light to the projection lens (6); and a plate-like transmission element (4) which transmits the concentrated light, the transmission element (4) being arranged between the condensing optical element (3, 37, 38) and the wavelength selection element (7) and rotatable about an axis (S2) perpendicularly is supported to an optical axis (Cp) of the projection lens (6), wherein a light concentration position of the concentrated light is between the condensing optical element (3, 37, 38) and the projection lens (6), the light concentration position between the transmission element (4 ) and the projection lens (6) is arranged, wherein the wavelength selection element (7) contains a plurality of regions (7a, 7b, 7c) which transmit light of different wavelengths and which in a direction (Y-axis direction) perpendicular to the optical axis (Cp) of the projection lens (6), and wherein the lighting device (103, 108) rotates the transmission element (4) to the position at which the concentrated light the wavelength Selector element (7) is able to move in a direction (Y-axis direction) perpendicular to the optical axis (Cp) of the projection lens (6) and thereby change the color temperature of the light projected by the projection lens (6). Lighting device (103, 108) according to Claim 1 wherein, in an optical axis (Cp) direction, the light concentration position coincides with a focal position of the projection lens (6). Lighting device (108) according to one of the Claims 1 or 2 , further comprising a collimator lens (20r, 20g, 20b) which converts the light emitted by the light source (2r, 2g, 2b) into parallel light, the lighting device (108) having a plurality of light sources (2r, 2g, 2b), wherein the collimator lens (20r, 20g, 20b) emits a plurality of parallel light beams corresponding to the light sources, and the plurality of parallel light beams are parallel to each other, and wherein the condensing optical element (38) concentrates the light beams emitted from the collimator lens (20r, 20g, 20b). Headlight device, comprising the lighting device (103, 108) according to one of the Claims 1 until 3 .

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